System and method for the measurement and prediction of the charging efficiency of accumulators

ABSTRACT

The invention concerns a method comprising two fundamental steps. The first one is an innovative process of characterization of the energetic efficiency performed during a charging process of an accumulator, whereby one derives a series of information concerning: the dependency of the electric parameters of the accumulator on the state of charge; the dependency of the efficiency of the charging system on the voltage and current at the output of the charging system. The second step of the proposed method is a process of data calculation for the prediction of the energetic efficiency, wherein one simulates one or more charging processes. The method can be realized by means of a charging system able to perform both a standard process for charging the accumulator and a process of characterization of the energetic efficiency, and a process of prediction of the energetic efficiency.

The present invention concerns a system and method for the measurement and prediction of the charging efficiency of accumulators.

More in detail, the invention concerns a method that comprises an innovative process of characterization of the energetic efficiency carried out during a charging process of the accumulator, thank to which one obtains a series of information concerning the dependency of the electrical parameters of the accumulator on the state of charge (and possibly on the accumulator operating temperature) and concerning the dependency of the efficiency of the charging system on the voltage and current at the output of the charging system, and possibly also on the voltage at the input of the charging system (and possibly also on the operating temperature of the charging system). The method allows moreover to perform a step of prediction of the energetic efficiency wherein one simulates one or more charging processes on the basis of the data obtained in the above characterization process. According to the invention, the method can be realized by a charging system able to perform both a standard charging process of the accumulator, and a process of characterization of the energetic efficiency, as well as a process of prediction of the energetic efficiency. It is also possible to implement the method by a control system that can be used together with a conventional charging system.

DEFINITIONS

To the end of facilitate the correct interpretation of the invention, some terms utilized in the description and claims are specified in the following.

Accumulator of electric energy: device able to receive in input electric energy, storing it in any form and to supply it as electric energy.

Charging process of an accumulator: process wherein electric energy is provided to an accumulator of electric energy.

Discharging process of an accumulator: process wherein the accumulator supplies electric energy.

Charging power of an accumulator: electric power supplied to an electric energy accumulator in a given time instant of the charging process.

Charging efficiency of an accumulator: ratio between the total amount of energy stored into an accumulator during the charging process and the electric total amount of energy supplied by the charging system to the same accumulator during the charging process.

Discharging efficiency of an accumulator: ratio between the total amount of electric energy supplied by an accumulator at its output terminals during the discharge and the total amount of energy lost by the same accumulator during the discharging process.

Charging system: system provided of an input section and an output section, the system drawing electric energy from an energy source by the input section and supplying electric energy to an accumulator by the output section.

Efficiency of the charging system: ratio between the electric power supplied at the output of the charging system and the electric power drawn in input by the same charging system.

Electric parameters of the accumulator: parameters of the equivalent electric circuit with which the accumulator can be modeled during the charging phase.

Framework of the Invention and State of the Art

The known charging process of an accumulator may be schematized as shown in FIG. 1. The energy is supplied by a source 101 to a charging system 102, which in turn supplies energy to the accumulator 103. Unfortunately, this process is characterized by energy losses into the charging system, into the accumulator and the related connection, losses that depend by the charging power. For example, in FIG. 2 a) it is shown the trend 201 of the charging efficiency of a typical Lithium-ion battery as a function of the charging power, expressed in “C-rate”:

${C\text{-}{rate}} = \frac{{Charging}\mspace{14mu} {current}\mspace{14mu} {(A) \cdot 1}h}{{Accumulator}\mspace{14mu} {capacity}\mspace{14mu} \left( {A\; h} \right)}$

The profile of FIG. 2 a) takes into account only the losses into the accumulator. However, also the efficiency of the charging system depends on the charging power. In the graph 202 of FIG. 2 b), a typical trend of the overall efficiency of the charging process (given by the product between the efficiency of the charging system and the charging efficiency of the accumulator) is shown as a function of the charging power (normalized with respect to the maximum power that can be supplied by the charging system and that can be absorbed by the accumulator).

Whilst the charging efficiency of the accumulator has typically a monotonically decreasing trend, the overall charging efficiency decreases in a substantial manner both for high and low levels of charging power. Hence, the fact of charging the accumulator in the slowest possible way is not synonymous of optimization of the overall charging efficiency. One derives therefore that knowing exactly the dependency of the overall charging efficiency on the charging power may be fundamental to consciously fix the charging power. Moreover, in scenarios providing for the use of a smart electric grid, this may allow to implement systems and charging methods that permit the optimization of the energetic efficiency of accumulators, such as for example the batteries of the electric vehicles, or dedicated batteries systems wherein the energy is to be accumulated from discontinuous renewable sources (solar, wind). Clearly, the relationship between the charging efficiency and power depends on the particular utilized charging system and accumulator.

In particular, it can be very useful for the end user to have at disposal a system that is able, even before performing the charging process of the accumulator, to estimate the efficiency of the future charge as a function of the current state of charge of the accumulator, the final desired state of charge and the charging speed that one wishes to set.

Clearly, the relationship between the overall energetic efficiency of the charging process and the charging power depends on the particular utilized charging system and accumulator. A first solution could be that of obtaining this relationship once and for all by means of a characterization of the system in the production phase, and then storing it.

Unfortunately, performing this operation with traditional charging systems by simply adding energy measurement systems presents a series of remarkable difficulties. Indeed, whilst one can measure the efficiency of the charging system by measuring directly the energy flowing at the input and at the output ports of the charging system in any operational condition, a direct measurement of the energy losses in the charging process of the accumulator cannot be performed. To understand better this problem, one can make reference to FIG. 3, that shows the energy flow in a charging process. The energy supplied by the source to the charging system 301 is indicated with E_(in). This energy can be measured directly by measuring, by means of suitable devices, the voltage (V_(in)) and current (I_(in)) at the terminals of the input port of the charging system:

E_(i n)(t) = ∫_(t₀)^(t)V_(i n)(τ)I_(i n)(τ)τ.

Because of the losses into the charging system, the latter supplies an energy 302 E_(sc)=η_(CH)E_(in), wherein η_(CH) (<1) indicates the efficiency of the charging system. This energy can also be measured directly by measuring, by means of suitable devices, the voltage (V_(out)) and current (I_(out)) at the terminals of the output port of the charging system:

E_(sc)(t) = ∫_(t₀)^(t)V_(out)(τ)I_(out)(τ)τ.

Hence, the efficiency of the charging system is directly the ratio between the two energies. Part of the energy E_(sc) supplied by the charging system is dissipated within the accumulator, which stores an energy 303 equal to E_(st)=η_(ac)E_(sc), wherein η_(ac) indicates the charging efficiency of the accumulator which dissipates as heat the remaining part equal to (1−η_(ac))E_(sc).

As one can easily understand, if one uses only devices for the measurement of voltage and current at the terminals of the accumulator, it is not possible to directly measure the energy really stored in the accumulator during the charging phase. Such an information could be in some way obtained indirectly in the subsequent discharge phase of the accumulator, which will supply an energy E_(oa)=η_(ad)E_(st) (E_(oa)=η_(ac)η_(ad)E_(sc)), wherein η_(ad) indicates the discharging efficiency of the accumulator. This energy is directly measurable by a measurement of the voltage at the terminals of the accumulator (V_(A)) and the current that flows in the accumulator (I_(A)), being:

E_(oa)(t) = ∫_(t₀)^(t)V_(A)(τ)I_(A)(τ)τ.

By the direct measurement of E_(oa) and E_(sc), it is possible to obtain the product between the charging efficiency and the discharging efficiency (E_(oa)/E_(sc)=η_(ac)η_(ad)) (the so-called “roundtrip efficiency”). In general, the two values of efficiency are different, so that it is not possible, in principle, to determine individually the charging efficiency and the discharging efficiency by a similar procedure. In any case, even admitting that the charging efficiency and the discharging efficiency are equal, there are other factors that complicate remarkably the estimation of the combined efficiency of charging system/accumulator.

Indeed, the charging efficiency of the accumulator at a parity of supplied energy, may vary also as a function of the initial and final state of charge of the charging process, owing to the fact that the internal resistors of the accumulator (that cause the power dissipation) vary in general with the state of charge. Moreover, most part of the accumulators utilized in the real applications (among which, for example, the lead acid and lithium batteries) are charged by a constant current phase, followed by a constant voltage phase, whose durations are strictly tied to the initial state of charge and the final desired one of the accumulator.

A further complication derives from the fact that the efficiency of the charging system also depends on the output voltage of the same charging system.

FIG. 4 shows the trend, as measured experimentally, of the efficiency of a charging system with varying output voltage and current.

Even supposing that the charging process is only performed at constant current, the output voltage of the charging system will vary during the charging process depending on the initial and final state of charge of the accumulator.

Due to the foregoing, if one wants to characterize the overall charging efficiency by simply measuring the energy absorbed by the source and the one stored in the accumulator, at least m·n complete accumulator charge/discharge cycles would be needed, wherein m represents the number of different charge currents that one wishes to explore and n represents the number of different initial states of charge that one wishes to explore.

It is clear that such a method would entail an enormous waste of time and energy for the determination of the relationship between charging efficiency and charging power.

Moreover, the described characterization method would provide accurate results only for the specific specimens of charging system and accumulator under examination and what is more in the life state that the same have at the moment of the characterization.

Indeed, with the above method one could only determine an average efficiency of the charging system (measured as the ratio between the total energy supplied at the output and that altogether absorbed at the input of the charging system during the process) during each of the m·n charging processes. Therefore such an efficiency measurement is strictly correlated to the specific accumulator connected during the characterization phase, which determines univocally the voltage-current pairs of the functioning of the charging system.

Therefore, the unavoidable aging of the components (charging system and accumulator), or their partial substitution will require to newly perform the whole characterization process.

Some of the discussed problems may be solved by estimating the energetic efficiency of the accumulator by a model of the energy losses on the same accumulator, as proposed by Er et al. (patent no US 2011/0035084), de Koning et al. (Modeling battery efficiency with parallel branches, 2004), Arai et al. (patent no US 2006/0273761, wherein however a method for the measurement of the energetic efficiency is not illustrated, rather one for the measurement of the coulombic efficiency, meant as the ratio between the amount of energy actually stored and that absorbed by the accumulator). As a matter of practice, the accumulator may be modeled by an equivalent electric circuit, obtained by the interconnection of circuit elements selected from a group comprising voltage generators, current generators, resistors, capacitors, inductors, diodes and the like.

A typical equivalent circuit of an accumulator is that shown in FIG. 5 501. The circuit is composed by two resistors R₁ and R₂, a capacitor C₂ and an ideal battery V_(ID). Typically all the electric parameters of the equivalent circuit show a dependency on the state of charge (SOC) of the accumulator. The correct determination of the electric parameters of the model, i.e. the values to attribute to the above-mentioned circuit elements, allows to re-create an electric behavior nearly identical to that of the real accumulator. The determination of the electric parameters is an operation that requires relatively short time-spans, and can be performed at any moment during the lifetime of the accumulator. Once such parameters are extracted, it is possible to determine in an accurate manner the charging efficiency of the accumulator for each admissible level of charging power by a suitable calculation algorithm. For example, by assuming that the accumulator is well described by the model in FIG. 5, the charging efficiency is determined by the energy absorbed by the ideal battery V_(ID) and that dissipated on the resistors R₁ and R₂. This has the undeniable advantage to allow the estimation of the efficiency of the accumulator by a circuital simulation of the system, and therefore without the necessity of physically discharging the accumulator to estimate the energy really inputted in the preceding charging phase.

There are different methods for the measurement of the equivalent electric parameters by which an accumulator can be modeled (T. Morita et al., patent no US 2010/0250038; T. Okada, U.S. Pat. No. 5,789,924; E. Barsoukov et al., U.S. Pat. No. 6,832,171). One of these consists in evaluating the time response of the voltage at the terminals of the accumulator to a current pulse, that is an operation performed by the known state-of-the-art testers (Bertness, patent no WO 2011/109343). However, it is not possible to use directly such testers to evaluate the electric parameters of the accumulator with varying SOC, unless one performs a discharge process (which is an inconvenient operation in terms of energy and time) of the accumulator simply to the end of sampling the parameters provided by the tester for different values of the SOC. Instead, the evaluation of the electric parameters with varying SOC may be performed easily if the charging system is able to pre-arrange suitable interruptions within a standard cycle of charging of the accumulator.

To this end, one can utilize more enhanced charging systems as proposed by the state of the art, as that proposed by Paryani (patent no US 2011/0077879) able to extract the electric parameters of the accumulator during the whole lifetime of the same accumulator to the end of evaluating its health state.

Once the electric parameters of the accumulator are obtained, it is possible to perform a circuital simulation of what happens on the battery, which would allow to obtain the charging efficiency of the accumulator in correspondence of a certain desired initial state of charge, final state of charge and charging time, and therefore to multiply the efficiency obtained by the experimentally obtained efficiency of the charging system for those desired values of initial state of charge, final state of charge and charging time.

Unfortunately, although a charging system incorporating directly the solution just described would allow to update the estimation of the charging efficiency of the accumulator during the whole lifetime of the system, it would not solve the problem relevant to the estimation of the efficiency of the charging system, which would keep tied to the specific accumulator connected during the characterization of the same charging system. In other terms, whilst the phase of characterization of the accumulator efficiency would be enough easy, it would be needed in any case to carry out m·n charging cycles (we repeat here that m represents the number of different charge currents that one wants to explore and n represents the number of different initial states of charge that one wants to explore) to characterize the charging system each time the accumulator is changed (or one deems it necessary because of aging of the same).

To avoid this remarkable loss of time (and electric energy), one could think to further improve the system by utilizing also a model of the energy losses into the charging system in the time simulation concerning the behavior of the accumulator. Obviously, in order to do this, a model of the efficiency curves of the charging system with varying output voltage and current is needed (FIG. 4).

This principle underlays some systems proposed in the state of the art, which utilize mathematical models for the losses of power systems (ac/dc and dc/dc converters) to the end of optimizing dynamically the performances of the system (Chapuis, patent no US 2009/0296432; Bose et al., patent no US 2009/309416).

The systems of this type are based on a characterization of the system that provides a measurements step wherein one determines the efficiency of the system for different output voltages and currents (and possibly of other parameters such as the input voltage and the temperature). The number of measurements to be performed varies on the basis of the accuracy that one wishes to obtain. For example, with reference to FIG. 4, if one wanted to determine the efficiency of the charging system for m output current values and n output voltage values, m·n measurement would be necessary. Surely this represents a less expensive procedure in terms of time with respect to performing m·n distinct charging processes. The fundamental problem is however that such a characterization process requires that the output of the charging system has to be disconnected from the accumulators and connected to a device that allows to make the charging system work in any point of the space output voltage/output current. Therefore, such a characterization procedure is suitable to be carried out possibly in the production phase. Moreover, such characterization should be performed, because of the unavoidable production tolerances, on a sufficiently large sample if not for each produced system, with a remarkable increase of fabrication costs. Certainly, this method is not suitable to be used easily by the end user at any moment of the lifetime of the system.

By virtue of the foregoing, it appears that it is not possible to obtain a charging system that is able to update in a rapid and effective way the efficiency profile in real time for the whole life of the system by the union of the different existing systems in the state of the art as discussed above.

It is object of the present invention a method for the characterization of the energetic efficiency of the group charging system/accumulator that allows to overcome the limits of the conventional systems.

As it will be illustrated in the following, the method according to the invention can be implemented by an intelligent charging system able to measure the efficiency and possibly to optimize automatically the charging parameters in order to maximize the energetic efficiency.

Obviously an intelligent charging system such as the one that will be illustrated could not solve the problem faced by most part of the users who already have got a charging system, in which cases it is little practical and economical to substitute the whole still functioning system with a new one to have the possibility of easily measuring the efficiency of the accumulator. In these cases, it would be more economical and comfortable to have the possibility of being equipped with a simple measurement tool to be used in addition to the charging system.

The foregoing discussion could suggest to the skilled man the use of a suitable tool comprising a certain number of voltage and current sensors to perform the measurement of the efficiency of the charging system and a connection device, connected between the charging system 102 and the accumulator 103, able to temporarily disconnect the accumulator from the charging system and connect it to a suitable measurement device to the end of determining its electrical parameters with varying state of charge. However, such a solution is unfeasible because typically the commercial charging systems, as a precaution, terminates automatically the charging process when the accumulator is disconnected from the same charging system. The present invention has as object also that of overcoming such a problem by introducing a further measuring system that will be illustrated in detail in the following.

Object and Subject-Matter of the Invention

The present invention has as object that of overcoming the limits of the conventional systems by introducing a method of characterization of the energetic efficiency of the group charging system/accumulator that can be used easily during and for the whole lifetime of the charging system, when the accumulator is ageing and even in case of substitution of the latter.

It is subject-matter of the present invention a method for the characterization of the energetic efficiency of the charging process of an accumulator, as in the annexed claim 1. Embodiments are given in the dependent claims.

It is further subject-matter of the present invention a method for the prediction of the energetic efficiency of the charging process of an accumulator, as in the annexed claim 6. Further embodiments are given in the dependent claims.

It is further subject-matter of the present invention a charging system for accumulators of electric energy, as in the annexed claim 9. Further embodiments are subject-matter of the dependent claims.

It is further specific subject-matter of the present invention a charge control system for an accumulator of electric energy, as in enclosed claim 14. Further embodiments are subject-matter of the dependent claims.

DESCRIPTION OF THE FIGURES

The invention will be now described by way of illustration but not by way of limitation, with reference to the drawings of the enclosed figures, wherein:

FIG. 1 shows a block diagram of the group charging-system/accumulator;

FIG. 2 shows a graph of the dependency of the charging efficiency on the charging power for a Li-ion battery (a) and a typical trend of the overall efficiency of the charging process as a function of the charging power (b);

FIG. 3 shows the flow of energy in a charging process;

FIG. 4 shows the efficiency of the charging system with varying output voltage and current applied to the accumulator;

FIG. 5 shows a possible equivalent model of an accumulator;

FIG. 6 shows a generic standard charging process composed by a step at constant current and a step at constant voltage;

FIG. 7 shows a graph illustrating the principle underlying the characterization method that is subject matter of the present invention;

FIG. 8 shows the real efficiency (continuous line) and the efficiency reconstructed according to the invention (dashed line) of the charging system for different output current and voltage values and constant input voltage;

FIG. 9 shows the real efficiency (continuous line) and the efficiency reconstructed according to the invention (dashed line) of the charging system for different input voltage and current values and constant output voltage;

FIG. 10 shows a charging process according to the invention including a given number of steps of measurement of the charging system efficiency and steps of determination of the electrical parameters of the accumulator;

FIG. 11 shows a possible implementation of the charging system implementing the method proposed according to the invention;

FIG. 12 shows a principle diagram of the functioning of the charge control system proposed according to the invention;

FIG. 13 shows a possible implementation of the charge control system proposed according to the invention;

FIG. 14 shows a possible implementation of the charge control system comprising also a voltage generator, according to the invention.

DETAILED DESCRIPTION OF THE EMBODIMENTS OF THE INVENTION

The following description has the aim of illustrating the general principle and some possible implementations of the invention, but it does not have to be considered as limiting.

According to an aspect of such an invention, it is proposed an innovative method that allows to characterize easily, at any moment of the lifetime of the system, the overall performances in terms of energetic efficiency of the particular utilized charging-system/accumulator with varying charging parameters (charging power, initial state of charge, final state of charge, temperature, state of ageing).

The proposed method allows to obtain the information necessary to the characterization of the energetic efficiency by means of a single process of characterization of the energetic efficiency (or in any case by a limited number of characterization processes), that consists of a phase of characterization of the charging system and a phase of characterization of the accumulator, that are per se realizable independently. Such phases of characterization are performed during an accumulator charging process on the basis of a determined number of measurements obtained by exploiting the natural evolution of the pair voltage/current at the terminals of the accumulator connected at the output of the charging system.

In order to explain the functioning of the method, one will make reference to a standard charging algorithm wherein the charging process is composed by a first step at constant current (wherein the charging system behaves as a current generator) and a subsequent step at constant voltage (wherein the charging system behaves as a voltage generator), being such an algorithm utilized for most part of the accumulators on the market, such as for example the lead acid or Li-ion batteries.

The skilled person will recognize that this does not limit the general validity of the proposed method, which can be easily extended to charging algorithms that are different or used in other types of batteries.

The graph of FIG. 6 shows a typical trend of the voltage and current of an accumulator during a standard charging process composed by a step at constant current 601 and another one at constant voltage 602. As shown by the graph, in the step at constant current, the current at the output of the charging system does not vary (and is equal to the value indicated by I₁), whilst the voltage at the output of the charging system increases with increasing state of charge of the accumulator (passing from an initial voltage V_(B1) to a preset voltage V_(B5), which is the one that will be set in the subsequent step, by the charging system, for the charge at constant voltage).

Hence, with reference to FIG. 7 (that gives a typical trend of the efficiency of the charging system with varying output current and voltage) one deduces that in the step at constant current, the efficiency of the charging system naturally evolves along a trajectory 701 wherein the current outputting the system keeps constant (equal to I₁), whilst the voltage outputting the system increases with increasing state of charge of the accumulator (passing from V_(B1) to V_(B5)).

Concerning the step of characterization of the charging system, this natural evolution of the voltage on the accumulator is exploited to perform a first step of measurements composed by a pre-determined number of measurements of the efficiency of the charging system during subsequent time intervals wherein the charging system each time provides a constant charging current I_(ref) (I_(ref)=I₁ in the example at hand).

As it will be understood for the remainder of the description, the number of measurements performed during the different steps of the process of characterization within the charging process depends on the accuracy with which one wishes to characterize the efficiency of the system.

The above measurements performed at the same current I_(ref) allow to extract the relationship existing between the efficiency of the charging system and the output voltage, that is obtained by an interpolation function ƒ^(η) _(Vout) of the measured points, i.e.:

η_(CH)(V _(out) ,I _(ref))=ƒ^(η) _(V) _(out) (V _(out) ,I _(ref))  (1)

Such a function (as well as the other functions utilized by the proposed method) can be selected in general from a set of functions comprising polynomial functions, splines and the like, such a choice not affecting the quality of the method but only the computational effort for the processing system and the accuracy of the obtained values.

During the step of charging at constant voltage, the efficiency of the charging system evolves instead naturally along a trajectory 702 wherein the voltage at the output of the system keeps constant (equal to V_(B5) in the example at hand), whilst the current diminishes along time in correspondence of the increase of the state of charge of the accumulator.

This is particularly useful to perform a second step of measurements within the phase of characterization of the charging system. Such second step consists in a pre-determined number of measurements of the efficiency of the charging system at a reference voltage V_(ref) (V_(ref)=V_(B5) in the example) for different currents (in the example of FIG. 7 the number of measurements is arbitrarily chosen equal to three, carried out in correspondence to currents I₁, I₂, and I₃). By means of an interpolation of the measured points, one determines therefore an interpolating function ƒ^(η) _(Iout) that allows to express the efficiency of the charging system for a generic current I_(out) when the system output voltage is equal to the reference voltage V_(ref):

η_(CH)(V _(ref) ,I _(out))=ƒ^(η) _(I) _(out) (V _(ref) ,I _(out))  (2)

At this point, one performs a step of extrapolation wherein one utilizes a function G^(η) _(Vout) to calculate, according to the relationship:

η_(CH)(V _(out) ,I _(out))=G ^(η) _(Vout)[ƒ^(η) _(Iout)(V _(ref) ,I _(out)),V _(out)],  (3)

wherein G^(η) _(Vout) is a function obtained starting from ƒ^(η) _(Iout) by translating the latter starting from its value in correspondence of the pair (V_(ref), I_(out)) along the axis defined by the generic value V_(out) by a quantity that is function of the corresponding step of ƒ^(η) _(Vout) between V_(ref) and V_(out) when the output current of the charging system is equal to I_(ref), for example of a quantity exactly equal to said step.

As a matter of practice, one is translating ƒ^(η) _(out) in the space defined by the triple comprising the pair (V_(out), I_(out)) and a generic efficiency value, thus obtaining a function η_(CH)(V_(out), I_(out)) that gives an efficiency value for the generic pair (V_(out), I_(out)).

It deals with a function that allows to extrapolate the values of the efficiency of the charging system in correspondence of a generic pair voltage/current (V_(out), I_(out)) even outside the trajectory followed in the space (V_(out), I_(out)) by the accumulator during the process of characterization (in the example of FIG. 7 the two values of efficiency in correspondence of the pairs (V_(B4), I₂) 703 e (V_(B4), I₃) 704 are for example extrapolated). Although the values so obtained represent an extrapolation of the efficiency of the system in correspondence of the considered pairs (V_(out), I_(out)), it deals with an approximation that is as much accurate as the definition of the above functions G^(η) _(Vout) and ƒ^(η) _(Iout) is accurate.

For example, physical considerations concerning the typical dissipation processes of charging systems show that the functions G^(η) _(Vout) and ƒ^(η) _(Iout) can be conveniently defined as follows:

$\quad\begin{matrix} \left\{ \begin{matrix} {{f_{Iout}^{\eta}\left( {V_{ref},I_{out}} \right)} = \frac{V_{ref} \cdot I_{out}}{\begin{matrix} {{V_{ref} \cdot I_{out}} + {P_{0}\left( V_{ref} \right)} +} \\ {{{\alpha_{1}\left( V_{ref} \right)} \cdot I_{out}} + {{\alpha_{2}\left( V_{ref} \right)} \cdot I_{out}^{2}}} \end{matrix}}} \\ {{{G_{Vout}^{\eta}\left\lbrack {{f_{Iout}^{\eta}\left( {V_{ref},I_{out}} \right)},V_{out}} \right\rbrack} = {{f_{Iout}^{\eta}\left( {V_{ref},I_{out}} \right)} + {\beta_{1} \cdot \left( {V_{out} - V_{ref}} \right)}}},} \end{matrix} \right. & (4) \end{matrix}$

wherein β₁ is a constant real coefficient, and P₀(V_(ref)), α₁(V_(ref)) and α₂(V_(ref)) are coefficients assuming constant real values for a given value of V_(ref), such values being determined by means of at least two measurements performed in the first step of measurements and two measurements performed in the second step of measurements.

Obviously the illustrated characterization process is performed for a determined input voltage V_(in) of the system (constant in case the input voltage is continuous current (dc) or with constant amplitude in case it deals with an alternate voltage (ac)). For applications wherein the input voltage of the charging system may vary (such as for example the charging of accumulators from solar panels) one can take into account the further impact of this quantity on the efficiency of the system.

To this end, the proposed method provides also for the possibility to perform a third step of measurements of the efficiency of the charging system in correspondence to a determined number of different values of voltage V_(in) at the input terminals of the charging system (in the case of alternate sinusoidal voltages one may for example mean by variation of V_(in) the variation of its effective value). In general, this third step of measurements can be performed within the phase of characterization of the charging system of just one process of characterization wherein variations of V_(in) occur, or in a plurality of different processes of characterization performed in correspondence to different values of V_(in). After the above mentioned third step of measurements one derives, by interpolation of the measured values of the efficiency of the charging system, an interpolating function ƒ^(η) _(Vin) that allows to express the efficiency of the charging system for a generic value of V_(in) and a pair (V_(out), I_(out)) measured during the above third step of measurements. In this way, it is possible to calculate, similarly to the foregoing, according to the relationship:

η_(CH)(V _(in) ,V _(out) ,I _(out))=G ^(η) _(Vin) {G ^(η) _(Vout)[ƒ^(η) _(Iout)(V _(ref) ,I _(out)),V _(out)]}  (5)

a function that allows to extrapolate the values of the efficiency of the charging system (and consequently of the dissipated power) in correspondence of a generic triple (V_(in), V_(out), I_(out)) even outside the trajectory followed into the space (V_(in), V_(out), I_(out)) during the process of characterization. The function G^(η) _(Vin) is a function of translation in the space, in a way completely similar to the G^(η) _(Vout).

Even in this case, the number of measurements of efficiency to be performed in the different steps depends on the mathematical model chosen for the efficiency of the system. Therefore, the choice of a suitable mathematical model may be important to simplify the characterization process.

For example, experimental results show that the following formulation for the efficiency function comes out to be particularly convenient to succeed to characterize the system in a sufficiently accurate manner by a limited number of measurements:

$\begin{matrix} {{\eta_{CH}\left( {V_{i\; n},V_{out},I_{out}} \right)}==\frac{V_{out} \cdot I_{out}}{\begin{matrix} {{V_{out} \cdot I_{out}} + K_{0} + {A_{0}V_{i\; n}} + {B_{0}V_{out}} +} \\ {{\left( {K_{1} + {A_{1}V_{i\; n}} - {B_{1}V_{out}}} \right)I_{out}} + {\left( {K_{2} + {A_{2}V_{out}} - {B_{2}V_{i\; n}}} \right)I_{out}^{2}}} \end{matrix}}} & (6) \end{matrix}$

In this relationship K₀, K₁, K₂, A₀, A₁, A₂, B₀, B₁, B₂ are constant coefficients that can be derived by the interpolation of only nine values of efficiency of the charging system: two values measured in the first step of measurement of the charging system efficiency, two values measured in the second step of measurement of the charging system efficiency, three values measured in the third step of measurements and two values of efficiency determined in the step of extrapolation by using the function defined by the (3).

The following further simplification of the efficiency function allows instead to characterize the losses of the charging system by just one process of characterization carried out at constant V_(in) (at constant effective value in case of sinusoidal ac voltages):

$\begin{matrix} {{\eta_{CH}\left( {V_{i\; n},V_{out},I_{out}} \right)}==\frac{V_{out} \cdot I_{out}}{\begin{matrix} {{V_{out} \cdot I_{out}} + K_{0} + {A_{0}\left( {V_{i\; n} + V_{out}} \right)} +} \\ {{\left\lbrack {K_{1} + {A_{1}\left( {V_{i\; n} - V_{out}} \right)}} \right\rbrack I_{out}} + {\left\lbrack {K_{2} + {A_{2}\left( {V_{out} - V_{i\; n}} \right)}} \right\rbrack I_{out}^{2}}} \end{matrix}\;}} & (7) \end{matrix}$

Indeed the coefficients K₀, K₁, K₂, A₀, A₁, A₂ present in the expression are derivable by interpolation of six values of efficiency of the charging system as obtained in the same characterization process: two values measured in the first step of measurement of the charging system efficiency, two values measured in the second step of measurement of the charging system efficiency, and two values determined by extrapolation by using the function in (3), without the necessity to resort to the measurements provided in the third step at different V_(in).

This can be easily understood if one expresses the charging system efficiency as a function of the power P_(DCH) dissipated by the charging system (according to the relationship

$\left. {\eta_{CH} = \frac{V_{out} \cdot I_{out}}{{V_{out} \cdot I_{out}} + P_{DCH}}} \right)$

and one considers the following formulation for P_(DCH):

$\begin{matrix} \left\{ \begin{matrix} \begin{matrix} {{P_{DCH}\left( {V_{i\; n},V_{out},I_{out}} \right)} = {{P_{0}\left( {V_{i\; n},V_{out}} \right)} +}} \\ {{{\alpha_{1}\left( {V_{i\; n},V_{out}} \right)} \cdot I_{out}} + {{\alpha_{2}\left( {V_{i\; n},V_{out}} \right)} \cdot I_{out}^{2}}} \end{matrix} \\ {{P_{0}\left( {V_{i\; n},V_{out}} \right)} = {K_{0} + {A_{0}\left( {V_{i\; n} + V_{out}} \right)}}} \\ {{\alpha_{1}\left( {V_{i\; n},V_{out}} \right)} = {K_{1} + {A_{1}\left( {V_{i\; n} - V_{out}} \right)}}} \\ {{\alpha_{2}\left( {V_{i\; n},V_{out}} \right)} = {K_{2} + {A_{2}\left( {V_{out} - V_{i\; n}} \right)}}} \end{matrix} \right. & (8) \end{matrix}$

The coefficients P₀, α₁ and α₂ of the equation of P_(DCH) for a given pair (V_(in), V_(out)) may be obtained by means of three values measured in correspondence to three different current I_(out). With reference to the efficiency curves of FIG. 7, one may consider the three points obtained in correspondence to the output currents I₁, I₂, I₃ and for V_(out)=V_(B5) (and for a given value of V_(in) that is constant in the analysis).

Once the efficiency in correspondence of these three points is known, one can determine the dissipated power, and find the coefficients P₀(V_(in), V_(B5)), α₁(V_(in), V_(B5)) and α₂ (V_(in), V_(B5)) by inverting the following equation system:

$\quad\begin{matrix} \left\{ \begin{matrix} {{P_{DCH}\left( {V_{i\; n},V_{B\; 5},I_{1}} \right)} = {{P_{0}\left( {V_{i\; n},V_{B\; 5}} \right)} + {{\alpha_{1}\left( {V_{i\; n},V_{B\; 5}} \right)} \cdot I_{1}} + {{\alpha_{2}\left( {V_{i\; n},V_{B\; 5}} \right)} \cdot I_{1}^{2}}}} \\ {{P_{DCH}\left( {V_{i\; n},V_{B\; 5},I_{2}} \right)} = {{P_{0}\left( {V_{i\; n},B_{B\; 5}} \right)} + {{\alpha_{1}\left( {V_{i\; n},V_{B\; 5}} \right)} \cdot I_{2}} + {{\alpha_{2}\left( {V_{i\; n},V_{B\; 5}} \right)} \cdot I_{2}^{2}}}} \\ {{P_{DCH}\left( {V_{i\; n},V_{B\; 5},I_{3}} \right)} = {{P_{0}\left( {V_{i\; n},V_{B\; 5}} \right)} + {{\alpha_{1}\left( {V_{i\; n},V_{B\; 5}} \right)} \cdot I_{3}} + {{\alpha_{2}\left( {V_{i\; n},V_{B\; 5}} \right)} \cdot I_{3}^{2}}}} \end{matrix} \right. & (9) \end{matrix}$

The so determined values of P₀, α₁ and α₂ may therefore be utilized in the expression (4) to determine the interpolating function ƒ^(η) _(Iout).

From the two points measured at current h for voltages equal to V_(B4) and V_(B5) one can find instead the coefficient β₁ that allows to express the function G^(η) _(Vout) as shown in (4). At this point, once this relationship is known, one extrapolates the values of efficiency in correspondence of currents I₂ and I₃ and for V_(out)=V_(B4) by exploiting the following relationships according to the equation (3):

η_(CH)(V _(B4) ,I ₂)=G ^(η) _(Vout)[ƒ^(η) _(Iout)(V _(B5) ,I ₂),V _(B4)] and

η_(CH)(V _(B4) ,I ₃)=G ^(η) _(Vout)[ƒ^(η) _(Iout)(V _(B5) ,I ₃),V _(B4)].

Once such efficiency values are known, it is possible to derive the corresponding values of dissipated power and find the coefficients P₀ (V_(in), V_(B4)), α₁(V_(in), V_(B4)) and α₂(V_(in), V_(B4)) by inverting the following system of equations (starting from the formulation of P_(DCH) of the system (8) wherein one considers V_(out)=V_(B4) and I_(out) equal to I₁, I₂ and I₃).

$\begin{matrix} \left\{ \begin{matrix} \begin{matrix} {{P_{DCH}\left( {V_{i\; n},V_{B\; 4},I_{1}} \right)} = {{P_{0}\left( {V_{i\; n},V_{B\; 4}} \right)} +}} \\ {{{\alpha_{1}\left( {V_{i\; n},V_{B\; 4}} \right)} \cdot I_{1}} + {{\alpha_{2}\left( {V_{i\; n},V_{B\; 4}} \right)} \cdot I_{1}^{2}}} \end{matrix} \\ \begin{matrix} {{P_{DCH}\left( {V_{i\; n},V_{B\; 4},I_{2}} \right)} = {{P_{0}\left( {V_{i\; n},V_{B\; 4}} \right)} +}} \\ {{{\alpha_{1}\left( {V_{i\; n},V_{B\; 4}} \right)} \cdot I_{2}} + {{\alpha_{2}\left( {V_{i\; n},V_{B\; 4}} \right)} \cdot I_{2}^{2}}} \end{matrix} \\ \begin{matrix} {{P_{DCH}\left( {V_{i\; n},V_{B\; 4},I_{3}} \right)} = {{P_{0}\left( {V_{i\; n},V_{B\; 4}} \right)} +}} \\ {{{\alpha_{1}\left( {V_{i\; n},V_{B\; 4}} \right)} \cdot I_{3}} + {{\alpha_{2}\left( {V_{i\; n},V_{B\; 4}} \right)} \cdot I_{3}^{2}}} \end{matrix} \end{matrix} \right. & (10) \end{matrix}$

At this point, the values of the coefficients K₀, K₁, K₂, A₀, A₁, A₂ to be utilized in the expression (7) for the efficiency can be obtained easily by inverting the following systems of equations:

$\begin{matrix} \left\{ \begin{matrix} {{P_{0}\left( {V_{i\; n},V_{B\; 5}} \right)} = {K_{0} + {A_{0}\left( {V_{i\; n} + V_{B\; 5}} \right)}}} \\ {{P_{0}\left( {V_{i\; n},V_{B\; 4}} \right)} = {K_{0} + {A_{0}\left( {V_{i\; n} + V_{B\; 4}} \right)}}} \end{matrix} \right. & (11) \\ \left\{ \begin{matrix} {{\alpha_{1}\left( {V_{i\; n},V_{B\; 5}} \right)} = {K_{1} + {A_{1}\left( {V_{i\; n} - V_{B\; 5}} \right)}}} \\ {{\alpha_{1}\left( {V_{i\; n},V_{B\; 4}} \right)} = {K_{1} + {A_{1}\left( {V_{i\; n} - V_{B\; 4}} \right)}}} \end{matrix} \right. & (12) \\ \left\{ \begin{matrix} {{\alpha_{2}\left( {V_{i\; n},V_{B\; 5}} \right)} = {K_{2} + {A_{2}\left( {V_{B\; 5} - V_{i\; n}} \right)}}} \\ {{\alpha_{2}\left( {V_{i\; n},V_{B\; 4}} \right)} = {K_{2} + {A_{2}\left( {V_{B\; 4} - V_{i\; n}} \right)}}} \end{matrix} \right. & (13) \end{matrix}$

The accuracy that can be achieved in the phase of characterization of the charging system is stressed by the graphs in FIGS. 8 and 9, which show the real efficiency curves of a charging system (continuous line) and those estimated by the proposed method (dashed line) for different values of V_(in), V_(out) and I_(out).

Such curves have been obtained by a description of the efficiency expressed by the relationship (7), whose coefficients have been determined by just one charging process as discussed above.

Obviously, one can always increase at will the accuracy in the estimation of the relationship between efficiency of the system and the input voltage, by performing a pre-determined number (that is limited in any case) of characterization processes at different values of the input voltage (by exploiting the normal input voltage variations in the particular application or utilizing an ad-hoc voltage adjusting system interposed between the source and the input of the power section of the charging system).

Besides the algorithm discussed above for determining the charging system efficiency, the proposed characterization process provides a phase of characterization of the accumulator consisting in a series of steps of determination of the electrical parameters of the same accumulator. These steps of determination of the parameters are performed whenever the state of charge is incremented by a pre-determined quantity, by applying a current waveform to the accumulator (as selected from a set of signals comprising impulsive, step, sinusoidal and similar signals) and evaluating the corresponding time response of the voltage on the same accumulator. In the implementation preferred by the inventors, the steps of determination of the parameters are performed by setting to zero for a certain timespan the current supplied to the accumulator, obtaining trends of the output voltage and current of the charging system during a characterization process that appear altogether as shown in FIG. 10.

Obviously, this must not be understood by way of limitation, because in some situations one could think even to obtain an estimation of the above-mentioned parameters by exploiting the application of any other type of current and/or voltage waveform to the accumulator in the above-mentioned steps of determination of parameters, as for example the current and/or voltage waveform obtained naturally during the evolution of the charging process in the absence of further perturbation of the same charging process (for example of the type of the voltage and current waveforms shown in FIG. 6).

Once the electrical parameters of the accumulator (equivalent circuit) are known, the proposed method provides with a process of prediction of the energetic efficiency consisting in one or more simulations of a pre-determined number of charging processes with different time trends of the charging power.

Every circuit simulation of the process of prediction of the energetic efficiency may be carried out at any instant subsequent to the above-mentioned characterization process and consists of the following steps: one determines the value of the initial state of charge of the accumulator connected to the charging system (for example by reading the open-circuit voltage and/or by counting the electric charge according the so-called Coulomb counting method), and starting from this value, one simulates with a pre-determined timestep a charging process performed at a given charging power, determining at each timestep (t_(k)) of the simulation: the state of charge (SOC(t_(k))), the electrical parameters of the accumulator as a function of SOC(t_(k)), the voltage V_(out)(t_(k)) and the current I_(out)(t_(k)) on the accumulator, the power P_(DA)(t_(k)) dissipated by the dissipative elements of the equivalent circuit of the accumulator and the power P_(DCH)(t_(k)) dissipated by the charging system by using one of the functions η_(CH) found by the characterization process. Finally, one calculates the overall efficiency of the charging process η_(TOT) as the ratio between the energy actually stored into the accumulator and the energy absorbed altogether by the source from the initial time instant t_(I) to the final one t_(F), such final instant being determined by the desired final state of charge of the accumulator at the end of the charging process:

$\begin{matrix} {\eta_{TOT} = \frac{\sum\limits_{t_{K} = t_{I}}^{t_{F}}\left\lbrack {{{V_{out}\left( t_{K} \right)} \cdot {I_{out}\left( t_{K} \right)}} - {P_{DA}\left( t_{K} \right)}} \right\rbrack}{{\sum\limits_{t_{K} = t_{I}}^{t_{F}}{{V_{out}\left( t_{K} \right)} \cdot {I_{out}\left( t_{K} \right)}}} + {\sum\limits_{t_{K} = t_{I}}^{t_{F}}{P_{DCH}\left( t_{K} \right)}}}} & (14) \end{matrix}$

In some types of applications, it may be useful to determine the relationship between the charging efficiency and the temperature, because both the parameters of the accumulator and those of the charging system may be affected by temperature variations. In such cases, one can apply the same reasoning made with regards to the variations of the input voltage. According to an aspect of the present invention, one may perform a pre-determined number of measurements of the equivalent electrical parameters of the accumulator in correspondence to a pre-determined number of different values of the operating temperature T_(A) of the accumulator (such measurements may be carried out within of an only charging process or possibly in a plurality of different charging processes), and for each circuital element of the equivalent circuit of the accumulator one can obtain, by interpolation of the above measured values of the electrical parameters, an interpolating function expressing the relationship between the element of the equivalent circuit of the accumulator, the state of charge and the operating temperature of the same accumulator. Moreover, one may perform a further step of measurements of the efficiency of the charging system in correspondence to a pre-determined number of different values of the operating temperature T_(CH) of the charging system (even such measurements step can be performed within just one process of characterization or a plurality of different characterization processes), and obtain, by interpolation of the above-mentioned measured values of the charging system efficiency, a function η_(CH)(V_(in), V_(out), I_(out), T_(CH)) expressing the relationship between the efficiency of the charging system and a generic values quadruple (V_(in), V_(out), I_(out), T_(CH)).

Once the above-mentioned relationships between the accumulator electrical parameters, the charging system efficiency and the temperature are known, one can include the following steps in the process of prediction of the energetic efficiency:

a) one determines the initial operating temperature of the accumulator and the charging system before any process of prediction of the energy efficiency;

b) during each process of simulation of the charging process, one determines at each simulation iteration the operating temperature of the accumulator and that of the charging system by means of determined mathematical functions (polynomial, spline, etc.);

c) one uses such values of the operating temperature of the accumulator and of the charging system in the determination of the state of charge of the accumulator, the accumulator electrical parameters, voltage and current on the accumulator, the power dissipated by the dissipative elements of the accumulator equivalent circuit and the power dissipated by the charging system utilizing the function η_(CH)(V_(in), V_(out), I_(out), T_(CH)).

The proposed characterization method may be implemented by a suitable charging system, that is another subject-matter of the present invention.

A possible realization of such a system is schematized in FIG. 11. In the system 1101 (as delimited by the dashed line), one has a power section 1102 suitable to apply suitable voltage waveforms and/or current to the accumulator and supply electric energy to the accumulator during each charging process. Two voltage meter devices measure the voltage at the input terminals 1103 and output terminals of the charging system, whilst two current meter devices measure the current flowing in input 1105 and output 1106 to the charging system. These meter devices provide the measured data to a calculation device 1107 which implements the calculations needed by the discussed characterization method, deriving the accumulator electrical parameters and the function for the charging system efficiency. Such data are then sent to a memory storing device 1108, that stores them in order to be subsequently exploited by the calculation device implementing also the process of prediction of the energetic efficiency.

The discussed system may also include a device for the measurement of the operating temperatures of both the accumulator and the charging system during the charging process. This further information may be also sent to the calculation device to determine the charging efficiency even as a function of the temperature according to the above discussed method.

In general, the system may also include a device for exchanging data with outside. This can allow for example the user to fix constraints (maximum charging time, maximum charging current, final state of charge as desired at the end of the process) on the possible time trend of the charging power to be used during the simulation process.

Finally, in a possible embodiment, the charging system may be utilized to optimize automatically the charging process to obtain the best possible energetic efficiency. In this case, the system carries out a process of prediction of the energetic efficiency before performing a standard charging process. The prediction process consists in the execution of a certain number of simulations each relevant to a specific time trend of the charging process selected among all the admissible time trends. Therefore, on the basis of the results obtained by the simulations, the system automatically sets the parameters of the power section to optimize the subsequent standard charging process, so as to re-create the time trend of the charging power corresponding to the largest overall charging efficiency value obtained during the above-mentioned process of prediction.

Moreover, the charging system may be implemented also to the end of determining the trend of one or more economic indicators of the energy storage process (such as for example the cost and/or profit relevant to an accumulator charging process and the like) as a function of both the power chosen for the charging process of the accumulator and a possible price plan regime of the energy that varies during the charge. In this case, the time trend of the price of the electric energy may be communicated by devices external to the charging system or determined by prediction models.

According to this last aspect of the invention, it is also possible to implement a system that sets automatically the parameters of the power section to optimize the subsequent standard charging process, to obtain the time trend of the charging power corresponding to the optimal value of the economic indicator at issue obtained during the process of prediction. This can be useful because, in general, the only optimization of the energetic efficiency could not imply automatically the optimization of the economic indicator at issue. For example, it could happen that the time trend of the charging process that allows to obtain the maximum energetic efficiency implies the energy purchase during a time slot that is disadvantageous in terms of energy price plan.

As shown, the proposed charging system presents a series of remarkable advantages in comparison with the conventional systems. However, there are several practical situation wherein such a system could not satisfy the needs of users who already have got a charging system. In this case it could happen that the user doesn't want to substitute his own charging system with a new charging system that is able to predict the energetic efficiency of the charging process. To meet these needs, it is proposed an efficiency measurement system as well, which is based on a charge control system, to be used in addition to a conventional charging system, able to implement the proposed method of energetic efficiency characterization.

Such a system is based on the idea that, to the end of performing the above steps of determination of parameters provided by the discussed method, it is also possible to apply to the accumulator any current and/or voltage waveform during an accumulator standard charging process, by perturbing the charging process itself for a given timespan without disconnecting the accumulator from the charging system and without altering the functioning of the charging system. The concept is shown in FIG. 12, that gives a block diagram of the system, wherein a controllable load 1204 is connected in parallel to the accumulator 1203 between the latter and the output of the charging system 1202. When the load is deactivated (the current 1206 flowing at its terminals is null), the accumulator receives the entire current supplied by the charging system 1207, whilst when one operates the load (the current 1206 flowing at its terminals is not null), a part (or the whole) of the current supplied by the charging system is absorbed by the load. This entails a voltage variation at the terminals of the accumulator 1205, that can be used to determine the electrical parameters of the accumulator itself by a suitable calculation algorithm.

On the basis of the foregoing, the quantity of current absorbed by the terminals of the controllable load depends on the particular current and/or voltage waveform that one wants to apply to the accumulator during the steps of determination of the parameters of the accumulator according to the method subject matter of the invention. As discussed, in general, in some possible implementations of the characterization method, one could even decide to extract the accumulator electrical parameters by not perturbing the natural voltage and current waveforms applied to the accumulator itself in the standard charging process. In these cases, obviously, the proposed charge control system may be configured to absorb a null current by its terminals during the above-mentioned steps of parameters determination.

In a possible embodiment (FIG. 13), the proposed efficiency measurement system 1300 is directly connected in parallel to the charging system 1302, that is provided with an input section, which is electrically connected to an electric energy source 1301, and an output section, which is electrically connected to the accumulator 1303.

The proposed charge control system is provided with voltage and current meter devices 1304, 1306 that allow to measure, respectively, the voltage and current at the terminals of the input section and the output section of the charging system. The one or more current sensors may be realized by resistors placed in series, or in a version wherein the direct connection between the charging system and the accumulator without the interposition of devices in series is guaranteed, can be of inductive type, hall-effect type or the like.

The system is also provided with a controllable load device 1305, that is electrically connected to the output section of the charging system and is able to absorb electric current by its own terminals. Moreover, in a possible implementation, the load device may also supply current.

During an accumulator standard charging process carried out by the charging system, the controllable load device is suitably activated so as to apply a given current and/or voltage waveform to the accumulator to perform the steps of determination of the accumulator parameters as provided by the above discussed efficiency characterization method.

The functioning of the load device is managed by a control and processing device 1307, that activates the load whenever the state of charge is incremented of a pre-determined quantity and performs the algorithm of determination of the parameters of the accumulator on the basis of the values of voltage and current on the accumulator as measured by the measurement devices.

During the charging process, the control and processing device implements also the step of characterization of the charging system, by elaborating, according to the method above discussed, the data coming from the measurement devices and taken during a pre-determined number of measurements steps (such steps number depends, as above shown, on the type of implemented characterization method).

The information obtained during the phase of characterization of the energetic efficiency are therefore stored into a suitable memory storing device 1309, and may be made accessible to the outside of the system by a suitable communication device 1308 which allows the data exchange between the measurement system and one or more external devices.

Of course, the storage of the electric parameters makes possible also the calculation of the efficiency outside a characterization process. This is performed by the control and processing device, which may perform at any moment in the lifespan of the system a phase of prediction of the energetic efficiency according to the proposed method, for example to the end of providing the user with useful information on how to carry out the charging process.

The energy needed to the functioning of the elements of the measurement system is provided by a supply section 1310 that can receive energy by a separated source, or the same source from which the charging system takes energy.

In a further implementation of the system, the measurement system may also receive from outside data relevant to the accumulator charging efficiency and/or to the charging system efficiency by the communication device. For example, this can allow to input into the system initial data coming from a characterization phase performed by the manufacturer of the charging system and/or the accumulator. The system may also comprise one or more temperature sensors that allow to measure the operating temperatures of both the accumulator and the charging system, in order to predict the system energetic efficiency even with varying temperature according to the method above discussed.

The measurement system at issue may be realized in such a way to be operated from remote, possibly deciding when the accumulator characterization process has to be performed. In a possible implementation of the system, the system can allow also the option of automatic start of the characterization process, that can start when the system notices changed conditions. For example, the system may perform a process of absorption (or supply) of a test current, and evaluate whether the electrical parameters obtained from such a process deviates from those that are in the memory storage, and in the affirmative case it may carry out the whole characterization process. Or, according to another aspect of the invention, the system may take into consideration temperature intervals of a certain width, and decide to automatically perform a characterization process whenever, on the basis of the data stored into the storing device, it detects that the current operating temperature falls within a range of temperature wherein a process of characterization has never been performed.

In some cases, the access to the input and/or output terminals of the charging system may be not possible. In such cases, the measurement system may be connected at the input or output by suitable adapters that allow the electrical and mechanical interconnection between the charging system and the charge control system, possibly also without the help of specific equipments and knowledge. In a possible version, such adapter devices have simply an input section and two output sections electrically connected with each other. In another implementation, it is also possible to insert current sensor in series (for example resistive sensors “current shunts”) between the various ports of the adapters.

The different implementations of the charge control system as discussed till now are adequate in most part of the practical applications wherein the charging system recognizes the end of the charge by current or temperature measurements, or by using a timer. However, in a limited number of cases (as in some cases of charging systems for NiCd and NiMh batteries), the traditional systems use the so-called ΔV method to recognize the completion of the charging phase of the accumulator. In these cases, the charging is stopped when a negative variation of the voltage of the accumulator is detected. In the cases wherein the charging system utilizes the ΔV method, the adoption of the measurement system as so far described may cause the undesired stop of the charging process, because, since part of the current coming from the charging system deviates on the controlled load, one could cause a voltage negative variation on the accumulator. To fix this possible problem, a further implementation of the measurement system is proposed (FIG. 14). In this implementation, the system 1400 comprises also a voltage generator device 1413, that is connected by a switching block (switch 1) 1414 to the output section of the charging system 1402, and the accumulator 1403 is connected by another switching block (switch 2) 1415 to the output section of the charging system. In the normal functioning of the charging system, the switch 1 is “open” (the voltage generator is disconnected from the output section of the charging system) and the switch 2 is “closed” (the accumulator is connected to the output section of the charging system). When a current absorption (or supply) process starts by the controllable load 1405, the voltage generator generates a voltage with value equal to the one at the terminals of the accumulator in the time instant preceding the beginning of the absorption (or supply) process, the switch 2 is “open” (the accumulator is disconnected from the output section of the charging system) and the switch 1 is “closed” (the voltage generator is connected to the output section of the charging system) so as to emulate the presence of the accumulator at the output of the charging system.

The functioning of the discussed charge control system is managed by a control and processing unit 1407, configured to realize the method subject-matter of the present invention.

Similarly to the system of FIG. 13, also that of FIG. 14 is provided with voltage and current measurement devices 1404, 1406 which allow to measure, respectively, the voltage and current at the terminals of the input and output sections of the charging system. The one or more current sensors can be realized by resistors placed in series, or, in a version wherein the direct connection between the charging system and the accumulator without interposition of devices in series is guaranteed, such sensors can be of inductive-type, hall effect-type or the like.

The system may comprise also a storing device 1409 and a communication (I/O) device 1408 that allows the exchange of data between the measurement system and one or more external devices.

The energy needed for the functioning of the elements of the measurement system is supplied by a supply section 1410 that can receive energy from a separated source, or from the same source from which the charging system takes energy.

The system can further comprise also an adapter 1411 that allows the electrical and mechanical interconnection between the source 1401, the charging system and the charge control system, possibly also without the help of specific equipments and knowledge.

In a further possible implementation, the controllable load device and the voltage generator are implemented by just one device.

Moreover, in each of the discussed implementations, the control and processing device can be implemented even to the end of determining the trend of one or more economic indicators of the energy accumulation as above discussed.

According to the invention, it is given a method for the characterization of the energetic efficiency of the charging process of an accumulator, such a charging process being performed by means of a charging system provided with an input section and an output section and configured to take energy from an energy source by the input section and provide energy to the accumulator by the output section, the above method being performed within at least a charging process of the accumulator and being characterized by the execution of a step A.1 of characterization of the accumulator during said at least a charging process and a step A.2 of characterization of the charging system during said at least a charging process or at least a different charging process, these steps being performed in sequence or in parallel, for the characterization of the accumulator being performed the following steps:

A.1) defining an equivalent electric circuit characterized by a set of electrical parameters, by which it is possible to model the behavior of the accumulator, and repetitively carrying out a step of determination of the parameters of said set of electric parameters whenever the state of charge of the accumulator comes out to be increased by a pre-determined quantity, by performing the following sub-steps:

A.1.1) applying to the accumulator, by means of the charging system, a pre-determined current and/or voltage waveform, and

A.1.2) measuring, within a time interval, a given number of values of voltage across the accumulator and/or current flowing in the accumulator, and

A.1.3) interpolating the above voltage and/or current values measured in step A.1.2, determining an interpolating function ƒ^(fit) that reconstructs the time response of the voltage or current on the accumulator as a consequence of the application of the waveform of step A.1.1, and from this function obtaining and storing the values of said electric parameters; and for the characterization of the charging system being performed the following steps:

A.2) calculating a set of values of efficiency of the charging system, measuring the voltage V_(in) and the current I_(in) at the terminals of the input section and the voltage V_(out) and the current I_(out) at the terminals of the output section of the charging system, and calculating the ratio between the electric power supplied by the output section as calculated on the basis of V_(out) and I_(out), and the electric power absorbed by the input section as calculated on the basis of V_(in) and I_(in), by means of the following sub-steps:

A.2.1) measuring, during subsequent time intervals wherein the charging system provides a constant charging current I_(ref), a pre-determined number of voltage/current pairs (V_(out), I_(ref)) at the output of the charging system and (V_(in), I_(in)) at the input of the charging system, deriving the corresponding values of efficiency of the charging system;

A.2.2) determining, by interpolating the efficiency values obtained in step A.2.1, a function ƒ^(η) _(Vout) that provides the values of efficiency of the charging system as a function of a generic voltage V_(out) for said current I_(ref) at the output of the charging system;

A.2.3) measuring, during subsequent time intervals wherein the charging system provides a constant output voltage V_(ref), a pre-determined number of voltage/current pairs (V_(ref), I_(out)) at the output of the charging system and (V_(in), I_(in)) at the input of the charging system, calculating the corresponding values of efficiency of the charging system;

A.2.4) determining, by means of interpolation of the efficiency values of step A.2.3, a function ƒ^(η) _(Iout) providing values of efficiency of the charging system as a function of a generic current I_(out) for said voltage V_(ref) at the output of the charging system;

A.2.5) performing an extrapolation step wherein one uses the function ƒ^(η) _(Vout) calculated in step A.2.2 and the function ƒ^(η) _(Iout) calculated in step A.2.4 to calculate the values of the efficiency of the charging system η_(CH) in correspondence of a generic pair of voltage/current values (V_(out), I_(out)) according to a function:

η_(CH)(V _(out) ,I _(out))=G ^(η) _(Vout)[ƒ^(η) _(Iout)(V _(ref) ,I _(out)),V _(out)];

wherein G^(η) _(Vout) is a function obtained starting from ƒ^(η) _(Iout) and translating it from its value in correspondence of the pair (V_(ref), I_(out)), along the axis defined by the generic value V_(out), of a quantity that is function of the corresponding increment of ƒ^(η) _(Vout) between V_(ref) and V_(out) when the current at the output of the charging system is equal to I_(ref), for example of a quantity exactly equal to said increment; thus obtaining the efficiency values of the charging process of the accumulator as a function of the voltages and currents provided to the accumulator by the charging system.

According to an aspect of the invention, the function ƒ^(η) _(Iout) is:

${{f_{Iout}^{\eta}\left( {V_{ref},I_{out}} \right)} = \frac{V_{ref} \cdot I_{out}}{{V_{ref} \cdot I_{out}} + {P_{0}\left( V_{ref} \right)} + {{\alpha_{1}\left( V_{ref} \right)} \cdot I_{out}} + {{\alpha_{2}\left( V_{ref} \right)} \cdot I_{out}^{2}}}},$

wherein P₀(V_(ref)), α₁(V_(ref)) ed α₂(V_(ref)) are coefficients that assume constant real values for a given value of V_(ref).

According to a further aspect of the invention, the function G^(η) _(Vout) is of type:

G ^(η) _(Vout)[ƒ^(η) _(Iout)(V _(ref) ,I _(out)),V _(out)]=ƒ^(η) _(Iout)(V _(ref) ,I _(out))+β₁·(V _(out) −V _(ref)),

wherein β₁ is a coefficient having a real constant value.

According to an aspect of the invention, one performs step A.2 in said at least a charging process or in one or more different charging processes, and wherein one further carries out the following sub-steps:

A.2.6) measuring, during a pre-determined number of subsequent time intervals wherein the charging system receives as input at least a value of voltage V_(in) different with respect to the values of V_(in) as measured during steps A.2.1 and/or A.2.3, a pre-determined number of voltage/current pairs (V_(out), I_(out)) at the output of the charging system and (V_(in), I_(in)) at the input of the charging system, calculating the corresponding values of the efficiency of the charging system;

A.2.7) determining, by means of interpolation of the efficiency values determined in step A.2.6, a function ƒ^(η) _(Vin) that provides the values of the efficiency of the charging system as a function of a generic input voltage V_(in), thus obtaining by a method analogous to that of step A.2.5, thanks to the functions ƒ^(η) _(Vout) and ƒ^(η) _(Iout), a function η_(CH)(V_(in), V_(out), I_(out)) that allows to extrapolate the value of efficiency of the charging system as a function of the generic triple (V_(in), V_(out), I_(out)).

According to an aspect of the invention, the function of efficiency of the charging system is:

${{\eta_{CH}\left( {V_{i\; n},V_{out},I_{out}} \right)}==\frac{V_{out} \cdot I_{out}}{\begin{matrix} {{V_{out} \cdot I_{out}} + K_{0} + {A_{0}V_{i\; n}} + {B_{0}V_{out}} +} \\ {{\left( {K_{1} + {A_{1}V_{i\; n}} - {B_{1}V_{out}}} \right)I_{out}} + {\left( {K_{2} + {A_{2}V_{out}} - {B_{2}V_{i\; n}}} \right)I_{out}^{2}}} \end{matrix}}},$

K₀, K₁, K₂, A₀, A₁, A₂, B₀, B₁, B₂ being constant coefficients having real values and that can be derived by interpolation of a set of values including:

-   -   at least two among the values of efficiency of the charging         system measured in step A.2.1,     -   at least two among the values of efficiency of the charging         system measured in step A.2.3,     -   at least two among the values of efficiency of the charging         system extrapolated by using the function η_(CH)(V_(out),         I_(out)) of step A. A.2.5,     -   at least three among the values of efficiency of the charging         system measured in step A.2.6.

According to an aspect of the invention, one performs the following further step, for example instead of above-mentioned steps A.2.6 and A.2.7:

A.2.8) determining a function η_(CH)(V_(in), V_(out), I_(out)) that allows to extrapolate the value of efficiency of the charging system as a function of the generic triple (V_(in), V_(out), I_(out)) by means of an analytic expression, for example the following:

${\eta_{CH}\left( {V_{i\; n},V_{out},I_{out}} \right)}==\frac{V_{out} \cdot I_{out}}{\begin{matrix} {{V_{out} \cdot I_{out}} + K_{0} + {A_{0}\left( {V_{i\; n} + V_{out}} \right)} +} \\ {{\left\lbrack {K_{1} + {A_{1}\left( {V_{i\; n} - V_{out}} \right)}} \right\rbrack I_{out}} + {\left\lbrack {K_{2} + {A_{2}\left( {V_{out} - V_{i\; n}} \right)}} \right\rbrack I_{out}^{2}}} \end{matrix}}$

K₀, K₁, K₂, A₀, A₁, A₂ being constant coefficients with real values and that can be derived by interpolation of:

-   -   at least two among the values of efficiency of the charging         system measured in step A.2.1,     -   at least two among the values of efficiency of the charging         system measured in step A.2.3, and     -   at least two among the values of efficiency of the charging         system extrapolated using the function η_(CH)(V_(out), I_(out))         of step A.2.5.

According to an aspect of the invention, the characterization process is carried out within a charging process subdivided into a first charging step wherein the charging system behaves as a current generator and a second charging step wherein the charging system behaves as a voltage generator, the step A.2.1 being performed in said first charging step and the step A.2.3 being performed in said second charging step.

According to an aspect of the invention, the step A.1 and the step A.2 are carried out in correspondence of a given number of values of the operating temperature T of the overall system comprising the charging system and accumulator, to the end of characterizing the equivalent circuit and the charging process with varying operating temperature, determining, by interpolation of the performed measurements, a function η_(CH)(V_(in), V_(out), I_(out), T) that provides the values of the efficiency of the charging system as a function of a generic values quadruple (V_(in), V_(out), I_(out), T).

According to a different aspect of the invention, the step A.1 and the step A.2 are executed in correspondence of a given number of values of the operating temperature T_(A) of the accumulator and the operating temperature T_(CH) of the charging system, to the end of characterizing the charging process with varying operating temperature of the accumulator and charging system, determining for each electric parameter of the accumulator equivalent circuit, by interpolation of the carried-out measurements, a function providing the value of said electric parameter as a function of the state of charge and accumulator operating temperature T_(A) and determining, by interpolation of the carried-out measurements, a function η_(CH) (V_(in), V_(out), I_(out), T_(CH)) providing the values of the efficiency of the charging system as a function of a generic quadruple of values (V_(in), V_(out), I_(out), T_(CH)).

According to an aspect of the invention, it is given a method for the prediction of the energetic efficiency of the charging process of an accumulator, such a charging process being carried out by a charging system provided with an input section and an output section and suitable to take energy from a source by means of the input section and supply energy to the accumulator by means of the output section, the method utilizing the values of efficiency of the charging system and the electrical parameters of the accumulator equivalent circuit derived by the method according to invention as above, characterized by the execution of the following steps:

B.1) measuring the value of the initial state of charge of the accumulator connected to the charging system, and carrying out the following sub-steps:

B.1.1) carrying out a process of simulation of one or more charging process, each of such simulated processes being characterized by a given time trend of the charging power, that is defined as the electric power supplied by the accumulator in a given time instant of the charging process, the simulation of each charging process being carried out with a given simulation timestep, determining at each simulation step the corresponding time instant t_(k), the accumulator state of charge SOC(t_(k)), the accumulator electrical parameters as a function of SOC(t_(k)) (since the step A.1 allows obviously to determine the values of the electric parameters in correspondence of a finite number of the state of charge, the value of each parameter in correspondence of any value of SOC(t_(k)) can possibly be determined by interpolation of the values of the parameters as determined in step A.1), the voltage V_(out)(t_(k)) and the current I_(out)(t_(k)) at the output of the charging system, the power P_(DA)(t_(k)) dissipated by the accumulator equivalent circuit and the power P_(DCH)(t_(k)) dissipated by the charging system in correspondence of the pair (V_(out)(t_(k)), I_(out)(t_(k))), P_(DCH)(t_(k)) being calculated utilizing one of the efficiency functions of the charging system as obtained in steps A.2.5, A.2.7 and A.2.8 of the method of the invention as above, and

B.1.2) on the basis of the above values obtained at each simulation timestep, calculating for each simulated charging process the relationship:

$\eta_{TOT} = \frac{\sum\limits_{t_{K} = t_{I}}^{t_{F}}\left\lbrack {{{V_{out}\left( t_{K} \right)} \cdot {I_{out}\left( t_{K} \right)}} - {P_{DA}\left( t_{K} \right)}} \right\rbrack}{{\sum\limits_{t_{K} = t_{I}}^{t_{F}}{{V_{out}\left( t_{K} \right)} \cdot {I_{out}\left( t_{K} \right)}}} + {\sum\limits_{t_{K} = t_{I}}^{t_{F}}{P_{DCH}\left( t_{K} \right)}}}$

providing the overall efficiency of the charging process η_(TOT) as the ratio between the energy actually stored in the accumulator and the energy that has been absorbed from the source altogether from the initial time instant t_(I) to the final time instant t_(F), said final time instant being determined by the desired value of the final charge state of the accumulator at the end of the charging process.

According to an aspect of the invention, the following further steps are executed:

-   -   determining the initial operating system temperature before each         process of prediction of energetic efficiency, and     -   during each process of simulation of the charging process,         determining at each step the system operating temperature         T(t_(K)) by means of a pre-determined function of the power         dissipated by the accumulator and charging system, and utilizing         this value of the system operating temperature T(t_(K)) for the         determination of the state of charge of the accumulator         SOC(t_(k)), of the accumulator electrical parameters as a         function of SOC(t_(k)), of both the voltage V_(out)(t_(k)) and         the current I_(out)(t_(k)) outputting the charging system, of         the power P_(DA)(t_(k)) dissipated by the dissipative elements         of the equivalent circuit of the accumulator and of the power         P_(DCH)(t_(k)) dissipated by the charging system, by using the         function η_(CH)(V_(in), V_(out), I_(out), T) determined         according to the method of the invention.

According to a different aspect of the invention, the following steps are performed:

-   -   determining the initial operating temperature of the accumulator         and the charging system before each prediction process of the         energy efficiency, and     -   during each process of simulation of the charging process,         determining at each step the operating temperature of the         accumulator T_(A)(t_(K)) and the charging system T_(CH)(t_(K))         by pre-determined functions of the power dissipated by the         accumulator and the charging system, and utilizing such values         of the accumulator operating temperature T_(A)(t_(K)) and the         charging system T_(CH)(t_(K)) in the determination of the state         of charge of the accumulator SOC(t_(k)), of the electric         parameters of the accumulator as a function of both SOC(t_(k))         and T_(A)(t_(K)) by the functions determined according to the         method of the invention as above, of both the voltage         V_(out)(t_(k)) and the current I_(out)(t_(k)) outputting the         charging system, of the power P_(DA)(t_(k)) dissipated by the         dissipative elements of the equivalent circuit of the         accumulator and of the power P_(DCH)(t_(k)) dissipated by the         charging system by the function η_(CH)(V_(in), V_(out), I_(out),         T_(CH)) determined according to the method as above.

According to an aspect of the invention, the value of at least an economic indicator relevant to energy storage is further determined, such as for example the cost relevant to an accumulator charging process, the method further comprising the execution of the following steps:

-   -   determining a function m(t) that provides the relationship         between the electric energy rate and the charging time t;     -   determining a function c[m(t)] that provides the relationship         between said at least an economic indicator and the electric         energy rate at a given time instant;     -   at each step of each simulation process carried out during the         process of energetic efficiency prediction, determining also the         value c[m(t_(K))] of said at least an economic indicator, and,         on the basis of said values obtained at each simulation         timestep, calculating the final value c_(F) of such at least an         economic indicator at the end of the charging process according         to the relationship

$c_{F} = {\sum\limits_{t_{K} = t_{I}}^{t_{F}}{{c\left\lbrack {m\left( t_{K} \right)} \right\rbrack}.}}$

According to an aspect of the invention it is provided a charging system for electric energy accumulators, such system being provided of an output section and an input section and being able to take up energy from a source by means of the input section and supply it to the accumulator by means of the output section, such system comprising the following elements:

-   -   a power section, able to supply electric energy to the         accumulator and to apply to it a pre-determined voltage and/or         current waveform,     -   an output voltage measurement device for the measurement of the         voltage at the terminals of the charging system output section,     -   an output current measurement device for the measurement of the         current that flows through the terminals of the charging system         output section,     -   an input voltage measurement device for the measurement of the         voltage at the terminals of the charging system input section,     -   an input current measurement device for the measurement of the         current flowing through the terminals of the charging system         input section,     -   a memory device, and     -   an electronic calculation device,         said system being able to perform a charging process of the         accumulator and a process of characterization of the energetic         efficiency according to the invention as above, wherein:     -   said power section is configured to apply to the accumulator a         voltage and/or current waveform according to step A.1.1;     -   said output voltage measurement device, said input voltage         measurement device, said input current measurement device and         said output current measurement device perform the measurements         of steps A.1.2, A.2.1, A.2.3;     -   said electronic calculation device performs the calculations of         steps A.1.3 and from A.2.1 to A.2.5;     -   said memory device is used to memorize the data calculated by         the method.

According to an aspect of the invention, said charging system further performs, by the included devices, the steps of the method for the characterization of the energetic efficiency of the charging process of an accumulator as above.

According to an aspect of the invention, a temperature measurement device is further comprised, which is configured for the execution of the temperature measurements above illustrated.

According to an aspect of the invention, the calculation device is configured to execute a process of energy efficiency prediction according to the method for the prediction of the energetic efficiency of the charging process of an accumulator of the invention, above illustrated.

According to an aspect of the invention, the electronic calculation device performs a process of energetic efficiency prediction before performing a charging process, and sets up automatically the functioning parameters of the power section to carry out the charging process, ensuring the time trend of the charging power corresponding to the largest value of overall efficiency η_(TOT) obtained during said process of prediction of the energetic efficiency, or corresponding to the smallest value of the economic indicator C_(F) calculated according to the invention as above specified.

According to an aspect of the invention, it is provided a charging control system for an electric energy accumulator that receives energy from a battery charger, which includes an input section and an output section and is able to take energy from a source by means of the input section and supply it to the accumulator by means of the output section presenting two terminals, said charging control system being characterized in that it comprises two control terminals suitable to be connected, directly or by means of one or more devices in series, to the two terminals of said output section of the battery charger, and in that it comprises:

-   -   a load device configured to draw and/or supply electric current         by said two control terminals during pre-defined time intervals         within a charging process carried out by the above-mentioned         battery charger, in such a way that a pre-determined current         and/or voltage waveform comes out to be applied to the         accumulator, according to step A.1.1 of the method as above;     -   at least a voltage sensing device that measures the voltage         difference between the terminals of the output section of the         battery charger and/or the voltage difference between the         terminals of the accumulator;     -   at least a current sensing device that measures the current         flowing into the terminals of the output section of the battery         charger;     -   at least a voltage sensing device that measures the voltage         difference between the terminals of the input section of the         battery charger, and     -   at least a current sensing device that measures the current         flowing into the terminals of the input section of the battery         charger;         said sensing devices being configured to perform the         measurements of the steps of the method according to the         invention above, as well as:     -   at least a memory device that allows the storage of the         measurement data;     -   an electronic control and processing device;         configured to carry out the calculations and/or simulations         according to the steps of the method according to the invention.

According to an aspect of the invention, there are also one or more temperature sensing devices that measure the accumulator operating temperature and the charging system operating temperature.

According to an aspect of the present invention, the system comprises at least a switching block connected in series between the terminals of the output section of the battery charger and the terminals of the accumulator, such a switching block being controlled by the electronic control and processing device in such a way to electrically disconnect the accumulator from the output section of the battery charger during the time intervals wherein the load device draws or supplies current, and to electrically connect the accumulator to the output section of the battery charger in the remaining time intervals, the system further comprising the following elements:

-   -   a voltage generator provided with two terminals suitable to be         electrically connected, directly or by one or more devices in         series, to the terminals of the battery charger output section,         said voltage generator being able to establish a voltage         difference between its terminals, such voltage difference being         determined by the electronic control and processing device;     -   at least a switching block connected in series between the         terminals of the above voltage generator and the terminals of         the output section of the battery charger, such switching block         being controlled by the electronic control and processing device         in such a way to electrically connect the voltage generator to         the output section of the battery charger during the time         intervals wherein the load device draws or supplies current, and         to electrically disconnect the voltage generator from the output         section of the battery charger in the remaining time intervals.

According to an aspect of the invention, the system further comprises a power section, suitable to supply current by said two control terminals.

The overall method consists therefore of two fundamental steps, the first of which may also be performed alone. The first is the implementation of an innovative process of characterization of the energetic efficiency carried out during a charging process of the accumulator. By means of such a process of characterization of the energetic efficiency, one obtains a series of information concerning:

-   -   the dependency of the electric parameters of the accumulator on         the state of charge and possibly also on the accumulator         operating temperature;     -   the dependency of the efficiency of the charging system on the         voltage and current at the terminals of the output section of         the charging system, and possibly also on the voltage at the         terminals of the input section of the charging system and the         operating temperature of the charging system.

The second step of the proposed method is the implementation of a process of numerical processing of the data for the prediction of the energetic efficiency, which consists in carrying out the simulation of one or more charging processes characterized by a given time trend of the charging power, on the basis of the initial conditions of the system (in terms of initial state of charge and possibly initial operating temperature) in the given instant wherein the simulation is performed.

According to an aspect of the invention, the proposed method is realized by a suitable charging system able to perform both a standard charging process of the accumulator, and a process of characterization of the energetic efficiency, as well as a process of prediction of the energetic efficiency, according to the enclosed claims.

According to another aspect of the invention, it is also proposed a charge control system that can be used jointly with a conventional charging system to implement a process of characterization of the energetic efficiency during a standard charging process of the accumulator and the possible subsequent step of numerical processing of the data for the prediction of the energetic efficiency, according to the enclosed system claims.

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Embodiments have been above described and some modifications of this invention have been suggested, but it should be understood that those skilled in the art can make variations and changes, without so departing from the related scope of protection, as defined by the following claims. 

1. Method for the characterization of the energetic efficiency of the charging process of an accumulator, such a charging process being performed by means of a charging system provided with an input section and an output section and configured to take energy from an energy source by the input section and provide energy to the accumulator by the output section, the above method being performed within at least a charging process of the accumulator and being characterized by the execution of a step A.1 of characterization of the accumulator during said at least a charging process and a step A.2 of characterization of the charging system during said at least a charging process or at least a different charging process, these steps being performed in sequence or in parallel, for the characterization of the accumulator being performed the following steps: A.1) defining an equivalent electric circuit characterized by a set of electrical parameters, by which it is possible to model the behavior of the accumulator, and repetitively carrying out a step of determination of the parameters of said set of electric parameters whenever the state of charge of the accumulator comes out to be increased by a pre-determined quantity, by performing the following sub-steps: A.1.1) applying to the accumulator, by means of the charging system, a pre-determined current and/or voltage waveform, and A.1.2) measuring, within a time interval, a given number of values of voltage across the accumulator and/or current flowing in the accumulator, and A.1.3) interpolating the above voltage and/or current values measured in step A.1.2, determining an interpolating function ƒ^(fit) that reconstructs the time response of the voltage or current on the accumulator as a consequence of the application of the waveform of step A.1.1, and from this function obtaining and storing the values of said electric parameters; and for the characterization of the charging system being performed the following steps: A.2) calculating a set of values of efficiency of the charging system, measuring a voltage V_(in) and a current I_(in) at the terminals of the input section and a voltage V_(out) and a current I_(out) at the terminals of the output section of the charging system, and calculating the ratio between the electric power supplied by the output section as calculated on the basis of V_(out) and I_(out), and the electric power absorbed by the input section as calculated on the basis of V_(in) and I_(in), by means of the following sub-steps: A.2.1) measuring, during subsequent time intervals wherein the charging system provides a constant charging current I_(ref), a pre-determined number of voltage/current pairs (V_(out), I_(ref)) at the output of the charging system and (V_(in), I_(in)) at the input of the charging system, deriving the corresponding values of efficiency of the charging system; A.2.2) determining, by interpolating the efficiency values obtained in step A.2.1, a function ƒ^(η) _(Vout) that that provides the values of efficiency of the charging system as a function of a generic voltage V_(out) for said current I_(ref) at the output of the charging system; A.2.3) measuring, during subsequent time intervals wherein the charging system provides a constant output voltage V_(ref), a pre-determined number of voltage/current pairs (V_(ref), I_(out)) at the output of the charging system and (V_(in), I_(in)) at the input of the charging system, calculating the corresponding values of efficiency of the charging system; A.2.4) determining, by means of interpolation of the efficiency values of step A.2.3, a function ƒ^(η) _(out) providing values of efficiency of the charging system as a function of a generic current I_(out) for said voltage V_(ref) at the output of the charging system; A.2.5) performing an extrapolation step wherein one uses the function ƒ^(η) _(Vout) calculated in step A.2.2 and the function ƒ^(η) _(Iout) calculated in step A.2.4 to calculate the values of the efficiency of the charging system η_(CH) in correspondence of a generic pair of voltage/current values (V_(out), I_(out)) according to a function: η_(CH)(V _(out) ,I _(out))=G ^(η) _(Vout)[ƒ^(η) _(Iout)(V _(ref) ,I _(out)),V _(out)]; wherein G^(η) _(Vout) is a function obtained starting from ƒ^(η) _(Iout) and translating it from its value in correspondence of the pair (V_(ref), I_(out)), along the axis defined by the generic value V_(out), of a quantity that is function of the corresponding increment of ƒ^(η) _(Vout) between V_(ref) and V_(out) when the current at the output of the charging system is equal to I_(ref), for example of a quantity exactly equal to said increment; thus obtaining the efficiency values of the charging process of the accumulator as a function of the voltages and currents provided to the accumulator by the charging system.
 2. Method according to claim 1, wherein one performs step A.2 in said at least a charging process or in one or more different charging processes, and wherein one further carries out the following sub-steps: A.2.6) measuring, during a pre-determined number of subsequent time intervals wherein the charging system receives as input at least a value of voltage V_(in) different with respect to the values of V_(in) as measured during the steps A.2.1 and/or A.2.3, a pre-determined number of voltage/current pairs (V_(out), I_(out)) at the output of the charging system and (V_(in), I_(out)) at the input of the charging system, calculating the corresponding values of the efficiency of the charging system; A.2.7) determining, by means of interpolation of the efficiency values determined in step A.2.6, a function ƒ^(η) _(Vin) that provides the values of the efficiency of the charging system as a function of a generic input voltage V_(in), thus obtaining by a method analogous to that of step A.2.5, thanks to the functions ƒ^(η) _(Vout) and ƒ^(η) _(Iout), a function η_(CH)(V_(in), V_(out), I_(out)) that allows to extrapolate the value of efficiency of the charging system as a function of the generic triple (V_(in), V_(out), I_(out)).
 3. Method according to claim 1, wherein one performs the following further step: A.2.8) determining a function η_(CH)(V_(in), V_(out), I_(out)) that allows to extrapolate the value of efficiency of the charging system as a function of the generic triple (V_(in), V_(out), I_(out)) by means of the following analytic expression: ${\eta_{CH}\left( {V_{i\; n},V_{out},I_{out}} \right)}==\frac{V_{out} \cdot I_{out}}{\begin{matrix} {{V_{out} \cdot I_{out}} + K_{0} + {A_{0}\left( {V_{i\; n} + V_{out}} \right)} +} \\ {{\left\lbrack {K_{1} + {A_{1}\left( {V_{i\; n} - V_{out}} \right)}} \right\rbrack I_{out}} + {\left\lbrack {K_{2} + {A_{2}\left( {V_{out} - V_{i\; n}} \right)}} \right\rbrack I_{out}^{2}}} \end{matrix}}$ K₀, K₁, K₂, A₀, A₁, A₂ being constant coefficients with real values and that can be derived by interpolation of: at least two among the values of efficiency of the charging system measured in step A.2.1, at least two among the values of efficiency of the charging system measured in step A.2.3, and at least two among the values of efficiency of the charging system extrapolated using the function η_(CH)(V_(out), I_(out)) of step A.2.5.
 4. Method according to claim 1, wherein the characterization process is carried out within a charging process subdivided into a first charging step wherein the charging system behaves as a current generator and a second charging step wherein the charging system behaves as a voltage generator, the step A.2.1 being performed in said first charging step and the step A.2.3 being performed in said second charging step.
 5. Method according to claim 1, wherein the step A.1 and the step A.2 are carried out in correspondence of a given number of values of the operating temperature T of the overall system comprising the charging system and accumulator, to the end of characterizing the equivalent circuit and the charging process with varying operating temperature, determining, by interpolation of the performed measurements, a function η_(CH)(V_(in), V_(out), I_(out), T) that provides the values of the efficiency of the charging system as a function of a generic values quadruple (V_(in), V_(out), I_(out), T).
 6. Method for the prediction of the energetic efficiency of the charging process of an accumulator, such a charging process being carried out by a charging system provided with an input section and an output section and suitable to take energy from a source by means of the input section and supply energy to the accumulator by means of the output section, the method utilizing the values of efficiency of the charging system and the electrical parameters of the accumulator equivalent circuit derived by the method according to claim 1, characterized by the execution of the following steps: B.1 measuring the value of the initial state of charge of the accumulator connected to the charging system, and carrying out the following sub-steps: B.1.1) carrying out a process of simulation of one or more charging process, each of such simulated charging processes being characterized by a given time trend of the charging power, that is defined as the electric power supplied to the accumulator in a given time instant of the charging process, the simulation of each charging process being carried out with a given simulation timestep, determining at each simulation step the corresponding time instant t_(k), the accumulator state of charge SOC(t_(k)), the accumulator electrical parameters as a function of SOC(t_(k)), the voltage V_(out)(t_(k)) and the current I_(out)(t_(k)) at the output of the charging system, the power P_(DA)(t_(k)) dissipated by the accumulator equivalent circuit and the power P_(DCH)(t_(k)) dissipated by the charging system in correspondence of the pair (V_(out)(t_(k)), I_(out)(t_(k))), P_(DCH)(t_(k)) being calculated utilizing an efficiency function of the charging system, and B.1.2) on the basis of the above values obtained at each simulation timestep, calculating the relationship: $\eta_{TOT} = \frac{\sum\limits_{t_{K} = t_{I}}^{t_{F}}\left\lbrack {{{V_{out}\left( t_{K} \right)} \cdot {I_{out}\left( t_{K} \right)}} - {P_{DA}\left( t_{K} \right)}} \right\rbrack}{{\sum\limits_{t_{K} = t_{I}}^{t_{F}}{{V_{out}\left( t_{K} \right)} \cdot {I_{out}\left( t_{K} \right)}}} + {\sum\limits_{t_{K} = t_{I}}^{t_{F}}{P_{DCH}\left( t_{K} \right)}}}$ providing the overall efficiency of the charging process η_(TOT) as the ratio between the energy actually stored in the accumulator and the energy that has been absorbed from the source altogether from the initial time instant t_(I) to the final time instant t_(F), said final time instant being determined by the desired value of the final charge state of the accumulator at the end of the charging process.
 7. (canceled)
 8. Method according to claim 6, wherein the value of at least an economic indicator relevant to energy storage is further determined, such as for example the cost relevant to an accumulator charging process, the method further comprising the execution of the following steps: determining a function m(t) that provides the relationship between the electric energy rate and the charging time t; determining a function c[m(t)] that provides the relationship between said at least an economic indicator and the electric energy rate at a given time instant; at each step of each simulation process carried out during the process of energetic efficiency prediction, determining also the value c[m(t_(K))] of said at least an economic indicator, and, on the basis of said values obtained at each simulation timestep, calculating the final value c_(F) of such at least an economic indicator at the end of the charging process according to the relationship $c_{F} = {\sum\limits_{t_{K} = t_{I}}^{t_{F}}{{c\left\lbrack {m\left( t_{K} \right)} \right\rbrack}.}}$
 9. Charging system for electric energy accumulators, such system being provided of an input section and an output section and being able to take up energy from a source by means of the input section and supply it to the accumulator by means of the output section, such system comprising the following elements: a power section, able to supply electric energy to the accumulator and to apply to it a pre-determined voltage and/or current waveform, an output voltage measurement device for the measurement of the voltage at the terminals of the charging system output section, an output current measurement device for the measurement of the current flowing through the terminals of the charging system output section, an input voltage measurement device for the measurement of the voltage at the terminals of the charging system input section, an input current measurement device for the measurement of the current flowing through the terminals of the charging system input section, a memory device, and an electronic calculation device, said system being able to perform a charging process of the accumulator and a process of characterization of the energetic efficiency according to claim 1, wherein: said power section is configured to apply to the accumulator a voltage and/or current waveform according to step A.1.1; said output voltage measurement device, said input voltage measurement device, said input current measurement device and said output current measurement device perform the measurements of steps A.1.2, A.2.1, A.2.3; said electronic calculation device performs the calculations of steps A.1.3 and from A.2.1 to A.2.5; said memory device is used to store the data calculated by the method.
 10. System according to claim 9, wherein said charging system further performs, by the included devices, the steps: A.2.6) measuring, during a pre-determined number of subsequent time intervals wherein the charging system receives as input at least a value of voltage V_(in) different with respect to the values of V_(in) as measured during the steps A.2.1 and/or A.2.3, a pre-determined number of voltage/current pairs (V_(out), I_(out)) at the output of the charging system and (V_(in), I_(in)) at the input of the charging system, calculating the corresponding values of the efficiency of the charging system; A.2.7) determining, by means of interpolation of the efficiency values determined in step A.2.6, a function ƒ^(η) _(Vin) that provides the values of the efficiency of the charging system as a function of a generic input voltage V_(in), thus obtaining by a method analogous to that of step A.2.5, thanks to the functions ƒ^(η) _(Vout) and ƒ^(η) _(Iout), a function η_(CH)(V_(in), V_(out), I_(out)) that allows to extrapolate the value of efficiency of the charging system as a function of the generic triple (V_(in), V_(out), I_(out)).
 11. System according to claim 9, wherein a temperature measurement device is further comprised, which is configured for the execution of temperature measurements, wherein step A.1 and step A.2 are carried out by the included devices, in correspondence of a given number of values of the operating temperature T of the overall system comprising the charging system and accumulator, to the end of characterizing the equivalent circuit and the charging process with varying operating temperature, determining, by interpolation of the performed measurements, a function η_(CH)(V_(in), V_(out), I_(out), T) that provides the values of the efficiency of the charging system as a function of a generic values quadruple (V_(in), V_(out), I_(out), T).
 12. System according to claim 9, wherein the calculation device is configured to execute a process of energy efficiency prediction.
 13. (canceled)
 14. Charging control system for an electric energy accumulator that receives energy from a battery charger, which includes an input section and an output section and is able to take energy from a source by means of the input section and supply it to the accumulator by means of the output section presenting two terminals, said charging control system being characterized in that it comprises two control terminals suitable to be connected, directly or by means of one or more devices in series, to the two terminals of said output section of the battery charger, and in that it comprises: a load device configured to draw electric current by said two control terminals during pre-defined time intervals in such a way that a current and/or voltage waveform comes out to be applied to the accumulator, according to step A.1.1 of the method of claim 1; at least a voltage sensing device that measures the voltage difference between the terminals of the output section of the battery charger and/or the voltage difference between the terminals of the accumulator; at least a current sensing device that measures the current flowing into the terminals of the output section of the battery charger; at least a voltage sensing device that measures the voltage difference between the terminals of the input section of the battery charger, and at least a current sensing device that measures the current flowing into the terminals of the input section of the battery charger; said sensing devices being configured to perform the measurements of the steps of the method according to claim 1, as well as: at least a memory device that allows the storage of the measurement data; an electronic control and processing device; configured to carry out the calculations and/or simulations according to the steps of claim
 1. 15. System according to claim 14, further comprising at least a switching block connected in series between the terminals of the output section of the battery charger and the terminals of the accumulator, such a switching block being controlled by the electronic control and processing device in such a way to electrically disconnect the accumulator from the output section of the battery charger during the time intervals wherein the load device draws current, and to electrically connect the accumulator to the output section of the battery charger in the remaining time intervals, the system further comprising the following elements: a voltage generator provided with two terminals suitable to be electrically connected, directly or by one or more devices in series, to the terminals of the battery charger output section, said voltage generator being able to establish a voltage difference between its terminals, such voltage difference being determined by the electronic control and processing device; at least a switching block connected in series between the terminals of the above voltage generator and the terminals of the output section of the battery charger, such switching block being controlled by the electronic control and processing device in such a way to electrically connect the voltage generator to the output section of the battery charger during the time intervals wherein the load device draws current, and to electrically disconnect the voltage generator from the output section of the battery charger in the remaining time intervals.
 16. Method according to claim 6, wherein one performs step A.2 in said at least a charging process or in one or more different charging processes, and wherein one further carries out the following sub-steps: A.2.6) measuring, during a pre-determined number of subsequent time intervals wherein the charging system receives as input at least a value of voltage V_(in) different with respect to the values of V_(in) as measured during the steps A.2.1 and/or A.2.3, a pre-determined number of voltage/current pairs (V_(out), I_(out)) at the output of the charging system and (V_(in), I_(in)) at the input of the charging system, calculating the corresponding values of the efficiency of the charging system; A.2.7) determining, by means of interpolation of the efficiency values determined in step A.2.6, a function ƒ^(η) _(Vin) in that provides the values of the efficiency of the charging system as a function of a generic input voltage V_(in), thus obtaining by a method analogous to that of step A.2.5, thanks to the functions ƒ^(η) _(Vout) and ƒ^(η) _(Iout), a function η_(CH)(V_(in), V_(out), I_(out)) that allows to extrapolate the value of efficiency of the charging system as a function of the generic triple (V_(in), V_(out), I_(out)).
 17. Method according to claim 6, wherein one performs the following further step: A.2.8) determining a function η_(CH)(V_(in), V_(out), I_(out)) that allows to extrapolate the value of efficiency of the charging system as a function of the generic triple (V_(in), V_(out), I_(out)) by means of the following analytic expression: ${\eta_{CH}\left( {V_{i\; n},V_{out},I_{out}} \right)}==\frac{V_{out} \cdot I_{out}}{\begin{matrix} {{V_{out} \cdot I_{out}} + K_{0} + {A_{0}\left( {V_{i\; n} + V_{out}} \right)} +} \\ {{\left\lbrack {K_{1} + {A_{1}\left( {V_{i\; n} - V_{out}} \right)}} \right\rbrack I_{out}} + {\left\lbrack {K_{2} + {A_{2}\left( {V_{out} - V_{i\; n}} \right)}} \right\rbrack I_{out}^{2}}} \end{matrix}}$ K₀, K₁, K₂, A₀, A₁, A₂ being constant coefficients with real values and that can be derived by interpolation of: at least two among the values of efficiency of the charging system measured in step A.2.1, at least two among the values of efficiency of the charging system measured in step A.2.3, and at least two among the values of efficiency of the charging system extrapolated using the function η_(CH)(V_(out), I_(out)) step A.2.5.
 18. Method according to claim 6, wherein the step A.1 and the step A.2 are carried out in correspondence of a given number of values of the operating temperature T of the overall system comprising the charging system and accumulator, to the end of characterizing the equivalent circuit and the charging process with varying operating temperature, determining, by interpolation of the performed measurements, a function η_(CH)(V_(in), V_(out), I_(out), T) that provides the values of the efficiency of the charging system as a function of a generic values quadruple (V_(in), V_(out), I_(out), T).
 19. Method according to claim 18, wherein the following further steps are executed: determining the initial operating system temperature before each process of prediction of energetic efficiency, and during each process of simulation of the charging process, determining at each step the system operating temperature T(t_(K)) by means of a pre-determined function of the power dissipated by the accumulator and charging system, and utilizing this value of the system operating temperature T(t_(K)) for the determination of the state of charge of the accumulator SOC(t_(k)), of the accumulator electrical parameters as a function of SOC(t_(k)), of both voltage V_(out)(t_(k)) and current I_(out)(t_(k)) outputting the charging system, of the power P_(DA)(t_(k)) dissipated by the dissipative elements of the equivalent circuit of the accumulator and of the power P_(DCH)(t_(k)) dissipated by the charging system, by using the function η_(CH)(V_(in), V_(out), I_(out), T).
 20. System according to claim 12, wherein the prediction of the energetic efficiency of the charging process of an accumulator is carried out by a charging system provided with an input section and an output section and suitable to take energy from a source by means of the input section and supply energy to the accumulator by means of the output section, the method utilizing the values of efficiency of the charging system and the electrical parameters of the accumulator equivalent circuit, characterized by the execution of the following steps: B.1 measuring the value of the initial state of charge of the accumulator connected to the charging system, and carrying out the following sub-steps: B.1.1) carrying out a process of simulation of one or more charging process, each of such simulated charging processes being characterized by a given time trend of the charging power, that is defined as the electric power supplied to the accumulator in a given time instant of the charging process, the simulation of each charging process being carried out with a given simulation timestep, determining at each simulation step the corresponding time instant h, the accumulator state of charge SOC(t_(k)), the accumulator electrical parameters as a function of SOC(t_(k)), the voltage V_(out)(t_(k)) and the current I_(out)(t_(k)) at the output of the charging system, the power P_(DA)(t_(k)) dissipated by the accumulator equivalent circuit and the power P_(DCH)(t_(k)) dissipated by the charging system in correspondence of the pair (V_(out)(t_(k)), I_(out)(t_(k))), P_(DCH)(t_(k)) being calculated utilizing an efficiency function of the charging system, and B.1.2) on the basis of the above values obtained at each simulation timestep, calculating the relationship: $\eta_{TOT} = \frac{\sum\limits_{t_{K} = t_{I}}^{t_{F}}\left\lbrack {{{V_{out}\left( t_{K} \right)} \cdot {I_{out}\left( t_{K} \right)}} - {P_{DA}\left( t_{K} \right)}} \right\rbrack}{{\sum\limits_{t_{K} = t_{I}}^{t_{F}}{{V_{out}\left( t_{K} \right)} \cdot {I_{out}\left( t_{K} \right)}}} + {\sum\limits_{t_{K} = t_{I}}^{t_{F}}{P_{DCH}\left( t_{K} \right)}}}$ providing the overall efficiency of the charging process η_(TOT) as the ratio between the energy actually stored in the accumulator and the energy that has been absorbed from the source altogether from the initial time instant t_(I) to the final time instant t_(F), said final time instant being determined by the desired value of the final charge state of the accumulator at the end of the charging process.
 21. System according to claim 20, wherein one performs step A.2 in said at least a charging process or in one or more different charging processes, and wherein one further carries out the following sub-steps: A.2.6) measuring, during a pre-determined number of subsequent time intervals wherein the charging system receives as input at least a value of voltage V_(in) different with respect to the values of V_(in) as measured during the steps A.2.1 and/or A.2.3, a pre-determined number of voltage/current pairs (V_(out), I_(out)) at the output of the charging system and (V_(in), I_(in)) at the input of the charging system, calculating the corresponding values of the efficiency of the charging system; A.2.7) determining, by means of interpolation of the efficiency values determined in step A.2.6, a function ƒ^(η) _(Vin) that provides the values of the efficiency of the charging system as a function of a generic input voltage V_(in), thus obtaining by a method analogous to that of step A.2.5, thanks to the functions ƒ^(η) _(Vout) and ƒ^(η) _(Iout), a function η_(CH)(V_(in), V_(out), I_(out)) that allows to extrapolate the value of efficiency of the charging system as a function of the generic triple (V_(in), V_(out), I_(out)).
 22. System according to claim 20, wherein one performs the following further step: A.2.8) determining a function η_(CH)(V_(in), V_(out), I_(out)) that allows to extrapolate the value of efficiency of the charging system as a function of the generic triple (V_(in), V_(out), I_(out)) by means of the following analytic expression: ${\eta_{CH}\left( {V_{i\; n},V_{out},I_{out}} \right)}==\frac{V_{out} \cdot I_{out}}{\begin{matrix} {{V_{out} \cdot I_{out}} + K_{0} + {A_{0}\left( {V_{i\; n} + V_{out}} \right)} +} \\ {{\left\lbrack {K_{1} + {A_{1}\left( {V_{i\; n} - V_{out}} \right)}} \right\rbrack I_{out}} + {\left\lbrack {K_{2} + {A_{2}\left( {V_{out} - V_{i\; n}} \right)}} \right\rbrack I_{out}^{2}}} \end{matrix}}$ K₀, K₁, K₂, A₀, A₁, A₂ being constant coefficients with real values and that can be derived by interpolation of: at least two among the values of efficiency of the charging system measured in step A.2.1, at least two among the values of efficiency of the charging system measured in step A.2.3, and at least two among the values of efficiency of the charging system extrapolated using the function η_(CH)(V_(out), I_(out)) step A.2.5.
 23. System according to claim 20, wherein the step A.1 and the step A.2 are carried out in correspondence of a given number of values of the operating temperature T of the overall system comprising the charging system and accumulator, to the end of characterizing the equivalent circuit and the charging process with varying operating temperature, determining, by interpolation of the performed measurements, a function η_(CH)(V_(in), V_(out), I_(out), T) that provides the values of the efficiency of the charging system as a function of a generic values quadruple (V_(in), V_(out), I_(out), T).
 24. System according to claim 23, wherein the following further steps are executed: determining the initial operating system temperature before each process of prediction of energetic efficiency, and during each process of simulation of the charging process, determining at each step the system operating temperature T(t_(K)) by means of a pre-determined function of the power dissipated by the accumulator and charging system, and utilizing this value of the system operating temperature T(t_(K)) for the determination of the state of charge of the accumulator SOC(t_(k)), of the accumulator electrical parameters as a function of SOC(t_(k)), of both voltage V_(out)(t_(k)) and current I_(out)(t_(k)) outputting the charging system, of the power P_(DA)(t_(k)) dissipated by the dissipative elements of the equivalent circuit of the accumulator and of the power P_(DCH)(t_(k)) dissipated by the charging system, by using the function η_(CH)(V_(in), V_(out), I_(out), T).
 25. System according to claim 20, wherein the value of at least an economic indicator relevant to energy storage is further determined, such as for example the cost relevant to an accumulator charging process, the method further comprising the execution of the following steps: determining a function m(t) that provides the relationship between the electric energy rate and the charging time t; determining a function c[m(t)] that provides the relationship between said at least an economic indicator and the electric energy rate at a given time instant; at each step of each simulation process carried out during the process of energetic efficiency prediction, determining also the value c[m(t_(K))] of said at least an economic indicator, and, on the basis of said values obtained at each simulation timestep, calculating the final value c_(F) of such at least an economic indicator at the end of the charging process according to the relationship $c_{F} = {\sum\limits_{t_{K} = t_{I}}^{t_{F}}{{c\left\lbrack {m\left( t_{K} \right)} \right\rbrack}.}}$
 26. System according to claim 25, characterized in that the electronic calculation device performs a process of energetic efficiency prediction before performing a charging process, and sets up automatically the functioning parameters of the power section to carry out the charging process, ensuring the time trend of the charging power corresponding to the largest value of overall efficiency η_(TOT) obtained during said process of prediction of the energetic efficiency, or corresponding to the smallest value of the economic indicator c_(F) calculated according to the relationship $c_{F} = {\sum\limits_{t_{K} = t_{I}}^{t_{F}}{{c\left\lbrack {m\left( t_{K} \right)} \right\rbrack}.}}$
 27. System according to claim 9, wherein said charging system further performs, by the included devices, the step: A.2.8) determining a function η_(CH)(V_(in), V_(out), I_(out)) that allows to extrapolate the value of efficiency of the charging system as a function of the generic triple (V_(in), V_(out), I_(out)) by means of the following analytic expression: ${\eta_{CH}\left( {V_{i\; n},V_{out},I_{out}} \right)}==\frac{V_{out} \cdot I_{out}}{\begin{matrix} {{V_{out} \cdot I_{out}} + K_{0} + {A_{0}\left( {V_{i\; n} + V_{out}} \right)} +} \\ {{\left\lbrack {K_{1} + {A_{1}\left( {V_{i\; n} - V_{out}} \right)}} \right\rbrack I_{out}} + {\left\lbrack {K_{2} + {A_{2}\left( {V_{out} - V_{i\; n}} \right)}} \right\rbrack I_{out}^{2}}} \end{matrix}}$ K₀, K₁, K₂, A₀, A₁, A₂ being constant coefficients with real values and that can be derived by interpolation of: at least two among the values of efficiency of the charging system measured in step A.2.1, at least two among the values of efficiency of the charging system measured in step A.2.3, and at least two among the values of efficiency of the charging system extrapolated using the function η_(CH)(V_(out), I_(out)) of step A.2.5.
 28. System according to claim 9, wherein said charging system further performs, by the included devices, the characterization process within a charging process subdivided into a first charging step wherein the charging system behaves as a current generator and a second charging step wherein the charging system behaves as a voltage generator, the step A.2.1 being performed in said first charging step and the step A.2.3 being performed in said second charging step. 